Pigtail-type optical receptacle

ABSTRACT

A pigtail-type optical receptacle includes a tubular ferrule having a through-hole extending in an axial direction, an optical fiber inserted into the through-hole such that part of the optical fiber extends outside the ferrule, a protective member covering the part of the optical fiber extending outside the ferrule, a tubular sleeve mounted on a front end side, outer surface of the ferrule, a holder tubular having holding the rear end side of the ferrule, and a tubular housing covering the ferrule and at least a portion of the sleeve. The ferrule through-hole includes first and second regions, the second region being disposed rearward of the first region, and the housing engaging the outer surface of the holder rearward of the first region.

CROSS-REFERENCE TO RELATED APPLICATIONS

This is a continuation application of U.S. patent application Ser. No.16/420,509, filed May 23, 2019, which is a continuation application ofU.S. patent application Ser. No. 16/029,172, filed July 6, 2018, whichis a continuation of International Application PCT/JP2017/018866, filedon May 19, 2017, which also claims priority to Japanese Application No.2016-101550, filed on May 20, 2016, Japanese Application No.2017-018454, filed on Feb. 3, 2017, Japanese Application No.2017-099521, filed on May 19, 2017, and Japanese Application No.2017-099522, filed on May 19, 2017. The entire contents of each of theabove related applications are incorporated herein by reference.

FIELD OF THE INVENTION

Embodiments described herein relate generally to a pigtail-type opticalreceptacle.

BACKGROUND OF THE INVENTION

An optical receptacle is used as a part for optically connecting anoptical fiber connector to an optical element such as a light receivingelement, a light-emitting element, or the like in an optical module ofan optical communication transceiver. For such an optical receptacle, apigtail-type optical receptacle also is known in which the optical fiberis drawn out from a ferrule.

For example, in JP-A 2012-230275 (Kokai), a pigtail-type opticalreceptacle is proposed in which a ferrule that holds an optical fiber isheld by a holder; and the holding force of the parts such as theferrule, the holder, etc., is increased by press-fitting the holder intoa case.

Also, in JP-A 2012-230275 (Kokai), because the rear end surface of theferrule is positioned on the rear end side of the press-fit region ofthe case, the pressure that is applied to the rear end portion of theferrule from the holder is reduced. Thereby, an undesirableconcentration of an external force locally at one portion of the opticalfiber at the rear end portion of the ferrule due to the inner diameterof the ferrule contracting due to the press-fitting can be suppressed.Also, the increase of the loss and the decrease of the strength of theoptical fiber due to the concentration of the external force can besuppressed; and the reliability of the pigtail-type optical receptaclecan be increased.

However, compared to a configuration in which the rear end of theferrule is disposed in the press-fit region, it is necessary to set theferrule and/or the holder to be long in the configuration in which therear end surface of the ferrule is positioned on the rear end side ofthe press-fit region of the case. Therefore, for the pigtail-typeoptical receptacle, it has been difficult to downsize in thelongitudinal direction of the receptacle main body portion (the portionfrontward of the drawn out optical fiber) including the ferrule, thecase, etc.

Generally, the configurations of optical transceivers are standardized;and the space of the electrical circuit including the optical elementsand the like is undesirably encroached when the receptacle main bodyportion is lengthened. Also, higher speeds are necessary for opticaltransceivers as the IP traffic increases; and the space that isnecessary for the electrical circuit is increasing due to the higherspeeds of the modulation rate of the optical signals emitted from theoptical elements, etc.

Therefore, for the pigtail-type optical receptacle, it is desirable tobe able to downsize without causing a decrease of the reliability due tothe concentration of the local external force in the optical fiber, etc.

SUMMARY OF THE INVENTION

According to an embodiment of the invention, a pigtail-type opticalreceptacle that includes a ferrule, an optical fiber, a protectivemember, a sleeve, a holder, and a housing is provided; the ferrule has atubular configuration and has a through-hole extending in an axialdirection; the optical fiber is held by the ferrule in a state of beinginserted into the through-hole and extends outside the ferrule from arear end side of the ferrule; the protective member covers a portion ofthe optical fiber extending outside the ferrule; the sleeve has atubular configuration, engages an outer surface of the ferrule, and ismounted on a front end side of the ferrule; the holder has a tubularconfiguration, engages the outer surface of the ferrule, and holds therear end side of the ferrule; the housing has a tubular configuration,engages an outer surface of the holder, and covers the ferrule and atleast a portion of the sleeve; the through-hole of the ferrule includesa first region and a second region; a width in an orthogonal directionof the through-hole in the first region corresponds to a width in theorthogonal direction of the optical fiber; the orthogonal direction isorthogonal to the axial direction; the second region is disposedrearward of the first region; the width in the orthogonal direction ofthe through-hole in the second region widens toward the rear end side ofthe ferrule; and the holder holds a portion of the outer surface of theferrule rearward of the first region.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view illustrating a pigtail-type opticalreceptacle according to a first embodiment;

FIG. 2A to FIG. 2C are cross-sectional views illustrating specificexamples of the ferrule according to the first embodiment;

FIG. 3 is a cross-sectional view illustrating a modification of thepigtail-type optical receptacle according to the first embodiment;

FIG. 4 is a cross-sectional view illustrating a modification of thepigtail-type optical receptacle according to the first embodiment;

FIG. 5 is a cross-sectional view illustrating a pigtail-type opticalreceptacle according to a second embodiment;

FIG. 6 is a cross-sectional view illustrating a modification of thepigtail-type optical receptacle according to the second embodiment;

FIG. 7 is a cross-sectional view illustrating a modification of thepigtail-type optical receptacle according to the second embodiment;

FIG. 8A and FIG. 8B are cross-sectional views illustrating modificationsof the pigtail-type optical receptacle according to the secondembodiment;

FIG. 9 is a cross-sectional view illustrating a pigtail-type opticalreceptacle according to a third embodiment;

FIG. 10A and FIG. 10B are cross-sectional views illustratingmodifications of the pigtail-type optical receptacle according to thethird embodiment;

FIG. 11 is a cross-sectional view illustrating a pigtail-type opticalreceptacle according to a fourth embodiment;

FIG. 12 is a partial cross-sectional view illustrating an enlargedportion of the pigtail-type optical receptacle according to the fourthembodiment; and

FIG. 13A to FIG. 13C are partial cross-sectional views illustratingmodifications of the pigtail-type optical receptacle according to thefourth embodiment.

DETAILED DESCRIPTION

A first invention is a pigtail-type optical receptacle that includes aferrule, an optical fiber, a protective member, a sleeve, a holder, anda housing; the ferrule has a tubular configuration and has athrough-hole extending in an axial direction; the optical fiber is heldby the ferrule in a state of being inserted into the through-hole andextends outside the ferrule from a rear end side of the ferrule; theprotective member covers a portion of the optical fiber extendingoutside the ferrule; the sleeve has a tubular configuration, engages anouter surface of the ferrule, and is mounted on a front end side of theferrule; the holder has a tubular configuration, engages the outersurface of the ferrule, and holds the rear end side of the ferrule; thehousing has a tubular configuration, engages an outer surface of theholder, and covers the ferrule and at least a portion of the sleeve; thethrough-hole of the ferrule includes a first region and a second region;a width in an orthogonal direction of the through-hole in the firstregion corresponds to a width in the orthogonal direction of the opticalfiber; the orthogonal direction is orthogonal to the axial direction;the second region is disposed rearward of the first region; the width inthe orthogonal direction of the through-hole in the second region widenstoward the rear end side of the ferrule; and the holder holds a portionof the outer surface of the ferrule rearward of the first region.

According to the pigtail-type optical receptacle, because the ferruleand at least a portion of the sleeve are housed in the housing, thelengths of the ferrule and/or the housing can be shortened compared to aconfiguration in which the rear end portion of the ferrule protrudesrearward of the housing. Also, the holder holds the portion of the outersurface of the ferrule rearward of the first region. Thereby, forexample, even in the case where the ferrule contracts, an undesirableconcentration of an external force in the optical fiber at the boundaryportion between the first region holding the optical fiber and thesecond region not holding the optical fiber can be suppressed.Accordingly, a pigtail-type optical receptacle that can be downsizedwithout causing a decrease of the reliability can be provided.

A second invention is the pigtail-type optical receptacle of the firstinvention, wherein a change of the width in the orthogonal direction ofthe through-hole in the second region has a curved configuration. Thecurved configuration is convex toward a central axis side of thethrough-hole.

According to the pigtail-type optical receptacle, the undesirableconcentration of the external force in the optical fiber at the boundaryportion between the first region and the second region can be suppressedfurther.

A third invention is the pigtail-type optical receptacle of the secondinvention, wherein the through-hole of the ferrule further includes athird region disposed rearward of the second region; and a change of thewidth in the orthogonal direction of the through-hole in the thirdregion has a linear configuration.

According to the pigtail-type optical receptacle, the undesirableconcentration of the external force in the optical fiber at the boundaryportion between the first region and the second region can be suppressedfurther.

A fourth invention is the pigtail-type optical receptacle of the firstinvention, wherein a front end of the protective member is positionedinside the second region of the through-hole.

According to the pigtail-type optical receptacle, the length of theportion of the optical fiber protruding from the protective member canbe shortened as much as possible. Thereby, for example, flexing of theoptical fiber can be suppressed; and the optical fiber can be insertedeasily into the through-hole of the ferrule. The manufacturability ofthe pigtail-type optical receptacle can be improved.

A fifth invention is the pigtail-type optical receptacle of the thirdinvention, wherein a front end of the protective member is positionedinside the third region of the through-hole.

According to the pigtail-type optical receptacle, the length of theportion of the optical fiber protruding from the protective member canbe shortened as much as possible. Thereby, for example, flexing of theoptical fiber can be suppressed; and the optical fiber can be insertedeasily into the through-hole of the ferrule. The manufacturability ofthe pigtail-type optical receptacle can be improved.

A sixth invention is the pigtail-type optical receptacle of the firstinvention, wherein the holder holds the rear end side of the ferrule bypress-fitting.

According to the pigtail-type optical receptacle, the ferrule can beheld appropriately by a simple configuration.

A seventh invention is the pigtail-type optical receptacle of the firstinvention, wherein a rear end of the holder is positioned rearward ofthe rear end of the ferrule; the holder surrounds a portion of theoptical fiber and a portion of the protective member; and the opticalfiber and the protective member further extend outside the holder andare fixedly bonded to the holder by an elastic member filled into thethrough-hole and into the holder.

According to the pigtail-type optical receptacle, deformation and/ortilting due to an external force of the portion of the optical fiberprotruding from the protective member can be suppressed. Also, theprotrusion from or the reverse retraction into the ferrule of the frontend of the optical fiber due to the application of the external forcecan be suppressed.

An eighth invention is the pigtail-type optical receptacle of theseventh invention, wherein an inner perimeter surface of the holderincludes a first inner perimeter portion and a second inner perimeterportion; the first inner perimeter portion engages the outer surface ofthe ferrule; the second inner perimeter portion is positioned rearwardof the first inner perimeter portion, protrudes inward from the firstinner perimeter portion, and surrounds a portion of the optical fiberand a portion of the protective member; a gap in the axial direction isprovided between the second inner perimeter portion and the rear end ofthe ferrule; and the elastic member is filled also into the gap.

According to the pigtail-type optical receptacle, the deformation and/orthe positional shift of the optical fiber front end portion due to theexternal force can be suppressed further.

A ninth invention is the pigtail-type optical receptacle of the firstinvention, wherein the holder has a first rear end surface and a secondrear end surface; and the second rear end surface is recessed frontwardof the first rear end surface on an outer perimeter side of the firstrear end surface.

According to the pigtail-type optical receptacle, for example, the firstrear end surface can be used as a receiving surface of the bonding agent(the elastic member) when fixedly bonding the optical fiber and theprotective member; and the second rear end surface can be used as apositional alignment surface between the holder and the housing.Thereby, the undesirable flowing of the bonding agent to the positionalalignment surface and the undesirable occurrence of the positional shiftbetween the holder and the housing can be suppressed. Also, theprotective member can be fixedly bonded in a longer region by settingthe length of the portion of the first rear end surface to be longerthan the length of the holder necessary to be held by the housing.Thereby, the deformation and/or the positional shift of the opticalfiber front end portion can be suppressed further.

A tenth invention is the pigtail-type optical receptacle of the firstinvention, wherein the outer surface of the holder includes a firstouter perimeter portion and a second outer perimeter portion; the firstouter perimeter portion is held by the housing; and the second outerperimeter portion is provided at a front end portion of the holder andis recessed inward from the first outer perimeter portion.

According to the pigtail-type optical receptacle, the portion where theholder is held by the housing can be shifted rearward; and theundesirable concentration of the external force in the optical fiber atthe boundary portion between the first region and the second region canbe suppressed further.

An eleventh invention is the pigtail-type optical receptacle of thefirst invention, wherein the holder includes a chamfer portion between arear end surface and an inner perimeter surface.

According to the pigtail-type optical receptacle, by providing thechamfer portion, the optical fiber can be inserted easily into theholder; and the manufacturability can be improved. Also, the chamferportion can be used as a bonding agent reservoir when fixedly bondingthe optical fiber and the protective member; and the undesirable flowingof the bonding agent to the positional alignment surface can besuppressed further.

A twelfth invention is the pigtail-type optical receptacle of theseventh invention, wherein the elastic member includes a protrusionprotruding outside the holder on the rear end side of the holder andcovering a corner portion between the rear end of the holder and anouter surface of the protective member.

According to the pigtail-type optical receptacle, the undesirablebending of the optical fiber locally at the corner portion between therear end of the holder and the outer surface of the protective memberwhen the load is applied by the external force can be suppressed.

A thirteenth invention is the pigtail-type optical receptacle of thefirst invention, wherein the housing holds the holder by press-fitting.

According to the pigtail-type optical receptacle, the holder can be heldappropriately by a simple configuration.

A fourteenth invention is the pigtail-type optical receptacle of thefirst invention, wherein the outer surface of the ferrule includes afirst contact portion contacting an inner perimeter surface of theholder; the outer surface of the holder includes a second contactportion contacting an inner perimeter surface of the housing; and anintermediate point in the axial direction of the second contact portionis positioned rearward of an intermediate point in the axial directionof the first contact portion.

According to the pigtail-type optical receptacle, for example, even inthe case where the holder is press-fitted into the housing, etc., theclamping force due to the press-fitting is dispersed in a wide region bythe second contact portion; and the undesirable concentration of theexternal force in the optical fiber at the boundary portion between thefirst region and the second region can be suppressed further.

A fifteenth invention is a pigtail-type optical receptacle that includesa ferrule, an optical fiber, a protective member, a sleeve, a holder,and a housing; the ferrule has a tubular configuration and has athrough-hole extending in an axial direction; the optical fiber is heldby the ferrule in a state of being inserted into the through-hole andextends outside the ferrule from a rear end side of the ferrule; theprotective member covers a portion of the optical fiber extendingoutside the ferrule; the sleeve has a tubular configuration, engages anouter surface of the ferrule, and is mounted on a front end side of theferrule; the holder has a tubular configuration, engages the outersurface of the ferrule, and holds the rear end side of the ferrule; thehousing has a tubular configuration, engages an outer surface of theholder, and covers the ferrule and at least a portion of the sleeve; thethrough-hole of the ferrule includes a first region and a second region;a width in an orthogonal direction of the through-hole in the firstregion corresponds to a width in the orthogonal direction of the opticalfiber; the orthogonal direction is orthogonal to the axial direction;the second region is disposed rearward of the first region; the width inthe orthogonal direction of the through-hole in the second region widenstoward the rear end side of the ferrule; and the width in the orthogonaldirection of the through-hole in the second region changes in a curvedconfiguration having a proportion of the change increasing toward therear end side.

According to the pigtail-type optical receptacle, because the ferruleand at least a portion of the sleeve are housed in the housing, thelengths of the ferrule and/or the housing can be shortened compared to aconfiguration in which the rear end portion of the ferrule protrudesrearward of the housing. Also, the width in the orthogonal direction ofthe through-hole in the second region changes in a curved configurationin which the proportion of the change increases toward the rear endside. Thereby, for example, even in the case where the ferrulecontracts, an undesirable concentration of an external force in theoptical fiber at the boundary portion between the first region holdingthe optical fiber and the second region not holding the optical fibercan be suppressed. Accordingly, a pigtail-type optical receptacle thatcan be downsized without reducing the reliability can be provided.

A sixteenth invention is a pigtail-type optical receptacle that includesa ferrule, an optical fiber, a protective member, a sleeve, a holder,and a housing; the ferrule has a tubular configuration and has athrough-hole extending in an axial direction; the optical fiber is heldby the ferrule in a state of being inserted into the through-hole andextends outside the ferrule from a rear end side of the ferrule; theprotective member covers a portion of the optical fiber extendingoutside the ferrule; the sleeve has a tubular configuration, engages anouter surface of the ferrule, and is mounted on a front end side of theferrule; the holder has a tubular configuration, engages the outersurface of the ferrule, and holds the rear end side of the ferrule; thehousing has a tubular configuration, engages an outer surface of theholder, and covers the ferrule and at least a portion of the sleeve; thethrough-hole of the ferrule includes a first region and a second region;a width in an orthogonal direction of the through-hole in the firstregion corresponds to a width in the orthogonal direction of the opticalfiber; the orthogonal direction is orthogonal to the axial direction;the second region is disposed rearward of the first region; the width inthe orthogonal direction of the through-hole in the second region widenstoward the rear end side of the ferrule; and the housing engages theouter surface of the holder rearward of the first region.

According to the pigtail-type optical receptacle, because the ferruleand at least a portion of the sleeve are housed in the housing, thelengths of the ferrule and/or the housing can be shortened compared to aconfiguration in which the rear end portion of the ferrule protrudesrearward of the housing. Also, the housing engages the outer surface ofthe holder rearward of the first region. Thereby, for example, theundesirable concentration, in the optical fiber at the boundary portionbetween the first region holding the optical fiber and the second regionnot holding the optical fiber, of the external force caused by thehousing engaging the outer surface of the holder can be suppressed.Accordingly, a pigtail-type optical receptacle that can be downsizedwithout reducing the reliability can be provided.

A seventeenth invention is the pigtail-type optical receptacle of thesixteenth invention, wherein the outer surface of the holder includes afirst outer perimeter portion and a second outer perimeter portion; thefirst outer perimeter portion is held by the housing; the second outerperimeter portion is provided at a front end portion of the holder andis recessed inward from the first outer perimeter portion; and the firstouter perimeter portion is positioned rearward of the first region.

According to the pigtail-type optical receptacle, the undesirableconcentration, in the optical fiber at the boundary portion between thefirst region holding the optical fiber and the second region not holdingthe optical fiber, of the external force caused by the housing engagingthe outer surface of the holder can be suppressed.

An eighteenth invention is the pigtail-type optical receptacle of thesixteenth invention, wherein an inner surface of the housing includes afirst inner perimeter portion and a second inner perimeter portion; thefirst inner perimeter portion engages the outer surface of the holder;the second inner perimeter portion is provided frontward of the firstinner perimeter portion and widens outward from the first innerperimeter portion; and the first inner perimeter portion is positionedrearward of the first region.

According to the pigtail-type optical receptacle, the undesirableconcentration, in the optical fiber at the boundary portion between thefirst region holding the optical fiber and the second region not holdingthe optical fiber, of the external force caused by the housing engagingthe outer surface of the holder can be suppressed.

A nineteenth invention is the pigtail-type optical receptacle of theeighteenth invention, wherein the second inner perimeter portion isconnected to the first inner perimeter portion via a tilted surface or acurved surface.

According to the pigtail-type optical receptacle, the housing can beformed easily even in the case where the first inner perimeter portionand the second inner perimeter portion are provided in the inner surfaceof the housing.

A twentieth invention is a pigtail-type optical receptacle that includesa ferrule, an optical fiber, a protective member, a sleeve, a holder,and a housing; the ferrule has a tubular configuration and has athrough-hole extending in an axial direction; the optical fiber is heldby the ferrule in a state of being inserted into the through-hole andextends outside the ferrule from a rear end side of the ferrule; theprotective member covers a portion of the optical fiber extendingoutside the ferrule; the sleeve has a tubular configuration, engages anouter surface of the ferrule, and is mounted on a front end side of theferrule; the holder has a tubular configuration, engages the outersurface of the ferrule, and holds the rear end side of the ferrule; thehousing has a tubular configuration, is mounted to the holder, andcovers the ferrule and at least a portion of the sleeve; thethrough-hole of the ferrule includes a first region and a second region;a width in an orthogonal direction of the through-hole in the firstregion corresponds to a width in the orthogonal direction of the opticalfiber; the orthogonal direction is orthogonal to the axial direction;the second region is disposed rearward of the first region; the width inthe orthogonal direction of the through-hole in the second region widenstoward the rear end side of the ferrule; the holder includes a flangeprotruding outward from the housing and being provided frontward of thesecond region; and the housing is mounted to the holder frontward of theflange.

According to the pigtail-type optical receptacle, because the ferruleand at least a portion of the sleeve are housed in the housing, thelengths of the ferrule and/or the housing can be shortened compared to aconfiguration in which the rear end portion of the ferrule protrudesrearward of the housing. Also, the holder includes the flange protrudingoutward from the housing and being provided frontward of the secondregion; and the housing is mounted to the holder frontward of theflange. Thereby, for example, the undesirable concentration, in theoptical fiber at the boundary portion between the first region holdingthe optical fiber and the second region not holding the optical fiber,of the external force caused by mounting the housing can be suppressed.Accordingly, a pigtail-type optical receptacle that can be downsizedwithout reducing the reliability can be provided.

A twenty-first invention is a pigtail-type optical receptacle thatincludes a ferrule, an optical fiber, a protective member, a sleeve, aholder, a housing, a first elastic member, and a second elastic member;the ferrule has a tubular configuration and has a through-hole extendingin an axial direction; the optical fiber is held by the ferrule in astate of being inserted into the through-hole and extends outside theferrule from a rear end side of the ferrule; the protective membercovers a portion of the optical fiber extending outside the ferrule; thesleeve has a tubular configuration, engages an outer surface of theferrule, and is mounted on a front end side of the ferrule; the holderhas a tubular configuration, engages the outer surface of the ferrule,and holds the rear end side of the ferrule; the housing has a tubularconfiguration, engages an outer surface of the holder, and covers theferrule and at least a portion of the sleeve; the first elastic memberis filled into the through-hole and into the holder; the second elasticmember covers a corner portion between a rear end of the holder and anouter surface of the protective member; the through-hole of the ferruleincludes a first region and a second region; a width in an orthogonaldirection of the through-hole in the first region corresponds to a widthin the orthogonal direction of the optical fiber; the orthogonaldirection is orthogonal to the axial direction; the second region isdisposed rearward of the first region; the width in the orthogonaldirection of the through-hole in the second region widens toward therear end side of the ferrule; the holder holds a portion of the outersurface of the ferrule rearward of the first region; the rear end of theholder is positioned rearward of the rear end of the ferrule; the holdersurrounds a portion of the optical fiber and a portion of the protectivemember; the optical fiber and the protective member further extendoutside the holder and are fixedly bonded to the holder by the firstelastic member; and a hardness of the second elastic member is lowerthan a hardness of the first elastic member.

According to the pigtail-type optical receptacle, because the ferruleand at least a portion of the sleeve are housed in the housing, thelengths of the ferrule and/or the housing can be shortened compared to aconfiguration in which the rear end portion of the ferrule protrudesrearward of the housing. Also, the holder holds a portion of the outersurface of the ferrule rearward of the first region. Thereby, forexample, even in the case where the ferrule contracts, an undesirableconcentration of an external force in the optical fiber at the boundaryportion between the first region holding the optical fiber and thesecond region not holding the optical fiber can be suppressed.Accordingly, a pigtail-type optical receptacle that can be downsizedwithout reducing the reliability can be provided.

Also, because the optical fiber and the protective member are fixedlybonded to the holder by the first elastic member, the deformation and/ortilting due to an external force of the portion of the optical fiberprotruding from the protective member can be suppressed. Also, theprotrusion from or the reverse retraction into the ferrule of the frontend of the optical fiber due to the application of the external forcecan be suppressed.

By providing the second elastic member, the starting point of thebending when the optical fiber is bent by handling, etc., can be distalto the first elastic member. In such a case, by setting the hardness ofthe second elastic member to be lower than the hardness of the firstelastic member, the stress that is applied to the protective member atthe boundary with the second elastic member can be suppressed even whenthe optical fiber is bent by handling, etc. Thereby, the damage of theprotective member at the vicinity of the boundary with the first elasticmember and/or the second elastic member, etc., can be suppressed; andthe risk of breakage of the optical fiber can be reduced further.

A twenty-second invention is a pigtail-type optical receptacle thatincludes a ferrule, an optical fiber, a protective member, a sleeve, aholder, a housing, a first elastic member, and a second elastic member;the ferrule has a tubular configuration and has a through-hole extendingin an axial direction; the optical fiber is held by the ferrule in astate of being inserted into the through-hole and extends outside theferrule from a rear end side of the ferrule; the protective membercovers a portion of the optical fiber extending outside the ferrule; thesleeve has a tubular configuration, engages an outer surface of theferrule, and is mounted on a front end side of the ferrule; the holderhas a tubular configuration, engages the outer surface of the ferrule,and holds the rear end side of the ferrule; the housing has a tubularconfiguration, engages an outer surface of the holder, and covers theferrule and at least a portion of the sleeve; the first elastic memberis filled into the through-hole and into the holder; the second elasticmember covers a corner portion between a rear end of the holder and anouter surface of the protective member; the through-hole of the ferruleincludes a first region and a second region; a width in an orthogonaldirection of the through-hole in the first region corresponds to a widthin the orthogonal direction of the optical fiber; the orthogonaldirection is orthogonal to the axial direction; the second region isdisposed rearward of the first region; the width in the orthogonaldirection of the through-hole in the second region widens toward therear end side of the ferrule; the width in the orthogonal direction ofthe through-hole in the second region changes in a curved configurationhaving a proportion of the change increasing toward the rear end side;the rear end of the holder is positioned rearward of the rear end of theferrule; the holder surrounds a portion of the optical fiber and aportion of the protective member; the optical fiber and the protectivemember further extend outside the holder and are fixedly bonded to theholder by the first elastic member; and a hardness of the second elasticmember is lower than a hardness of the first elastic member.

According to the pigtail-type optical receptacle, because the ferruleand at least a portion of the sleeve are housed in the housing, thelengths of the ferrule and/or the housing can be shortened compared to aconfiguration in which the rear end portion of the ferrule protrudesrearward of the housing. Also, the width in the orthogonal direction ofthe through-hole in the second region changes in a curved configurationin which the proportion of the change increases toward the rear endside. Thereby, for example, even in the case where the ferrulecontracts, an undesirable concentration of an external force in theoptical fiber at the boundary portion between the first region holdingthe optical fiber and the second region not holding the optical fibercan be suppressed. Accordingly, a pigtail-type optical receptacle thatcan be downsized without reducing the reliability can be provided.

Also, because the optical fiber and the protective member are fixedlybonded to the holder by the first elastic member, the deformation and/ortilting due to an external force of the portion of the optical fiberprotruding from the protective member can be suppressed. Also, theprotrusion from or the reverse retraction into the ferrule of the frontend of the optical fiber due to the application of the external forcecan be suppressed.

Also, by providing the second elastic member, the starting point of thebending when the optical fiber is bent by the handling, etc., can bedistal to the first elastic member. In such a case, by setting thehardness of the second elastic member to be lower than the hardness ofthe first elastic member, the stress that is applied to the protectivemember at the boundary with the second elastic member when the opticalfiber is bent by handling, etc., can be suppressed. Thereby, the damageof the protective member at the vicinity of the boundary with the firstelastic member and/or the second elastic member, etc., can besuppressed; and the risk of breakage of the optical fiber can be reducedfurther.

A twenty-third invention is a pigtail-type optical receptacle thatincludes a ferrule, an optical fiber, a protective member, a sleeve, aholder, a housing, a first elastic member, and a second elastic member;the ferrule has a tubular configuration and has a through-hole extendingin an axial direction; the optical fiber is held by the ferrule in astate of being inserted into the through-hole and extends outside theferrule from a rear end side of the ferrule; the protective membercovers a portion of the optical fiber extending outside the ferrule; thesleeve has a tubular configuration, engages an outer surface of theferrule, and is mounted on a front end side of the ferrule; the holderhas a tubular configuration, engages the outer surface of the ferrule,and holds the rear end side of the ferrule; the housing has a tubularconfiguration, engages an outer surface of the holder, and covers theferrule and at least a portion of the sleeve; the first elastic memberis filled into the through-hole and into the holder; the second elasticmember covers a corner portion between a rear end of the holder and anouter surface of the protective member; the through-hole of the ferruleincludes a first region and a second region; a width in an orthogonaldirection of the through-hole in the first region corresponds to a widthin the orthogonal direction of the optical fiber; the orthogonaldirection is orthogonal to the axial direction; the second region isdisposed rearward of the first region; the width in the orthogonaldirection of the through-hole in the second region widens toward therear end side of the ferrule; the housing engages the outer surface ofthe holder rearward of the first region; the rear end of the holder ispositioned rearward of the rear end of the ferrule; the holder surroundsa portion of the optical fiber and a portion of the protective member;the optical fiber and the protective member further extend outside theholder and are fixedly bonded to the holder by the first elastic member;and a hardness of the second elastic member is lower than a hardness ofthe first elastic member.

According to the pigtail-type optical receptacle, because the ferruleand at least a portion of the sleeve are housed in the housing, thelengths of the ferrule and/or the housing can be shortened compared to aconfiguration in which the rear end portion of the ferrule protrudesrearward of the housing. Also, the housing engages the outer surface ofthe holder rearward of the first region. Thereby, for example, theundesirable concentration, in the optical fiber at the boundary portionbetween the first region holding the optical fiber and the second regionnot holding the optical fiber, of the external force caused by thehousing engaging the outer surface of the holder can be suppressed.Accordingly, a pigtail-type optical receptacle that can be downsizedwithout reducing the reliability can be provided.

Also, because the optical fiber and the protective member are fixedlybonded to the holder by the first elastic member, the deformation and/ortilting due to an external force of the portion of the optical fiberprotruding from the protective member can be suppressed. Also, theprotrusion from or the reverse retraction into the ferrule of the frontend of the optical fiber due to the application of the external forcecan be suppressed.

By providing the second elastic member, the starting point of thebending when the optical fiber is bent by the handling, etc., can bedistal to the first elastic member. In such a case, by setting thehardness of the second elastic member to be lower than the hardness ofthe first elastic member, the stress that is applied to the protectivemember at the boundary with the second elastic member can be suppressedeven when the optical fiber is bent by handling, etc. Thereby, thedamage of the protective member at the vicinity of the boundary with thefirst elastic member and/or the second elastic member, etc., can besuppressed; and the risk of breakage of the optical fiber can be reducedfurther.

A twenty-fourth invention is a pigtail-type optical receptacle thatincludes a ferrule, an optical fiber, a protective member, a sleeve, aholder, a housing, a first elastic member, and a second elastic member;the ferrule has a tubular configuration and has a through-hole extendingin an axial direction; the optical fiber is held by the ferrule in astate of being inserted into the through-hole and extends outside theferrule from a rear end side of the ferrule; the protective membercovers a portion of the optical fiber extending outside the ferrule; thesleeve has a tubular configuration, engages an outer surface of theferrule, and is mounted on a front end side of the ferrule; the holderhas a tubular configuration, engages the outer surface of the ferrule,and holds the rear end side of the ferrule; the housing has a tubularconfiguration, is mounted to the holder, and covers the ferrule and atleast a portion of the sleeve; the first elastic member is filled intothe through-hole and into the holder; the second elastic member covers acorner portion between a rear end of the holder and an outer surface ofthe protective member; the through-hole of the ferrule includes a firstregion and a second region; a width in an orthogonal direction of thethrough-hole in the first region corresponds to a width in theorthogonal direction of the optical fiber; the orthogonal direction isorthogonal to the axial direction; the second region is disposedrearward of the first region; the width in the orthogonal direction ofthe through-hole in the second region widens toward the rear end side ofthe ferrule; the holder includes a flange protruding outward from thehousing and being provided frontward of the second region; the housingis mounted to the holder frontward of the flange; the rear end of theholder is positioned rearward of the rear end of the ferrule; the holdersurrounds a portion of the optical fiber and a portion of the protectivemember; the optical fiber and the protective member further extendoutside the holder and are fixedly bonded to the holder by the firstelastic member; and a hardness of the second elastic member is lowerthan a hardness of the first elastic member.

According to the pigtail-type optical receptacle, because the ferruleand at least a portion of the sleeve are housed in the housing, thelengths of the ferrule and/or the housing can be shortened compared to aconfiguration in which the rear end portion of the ferrule protrudesrearward of the housing. Also, the holder includes the flange protrudingoutward from the housing and being provided frontward of the secondregion; and the housing is mounted to the holder frontward of theflange. Thereby, for example, the undesirable concentration, in theoptical fiber at the boundary portion between the first region holdingthe optical fiber and the second region not holding the optical fiber,of the external force caused by mounting the housing can be suppressed.Accordingly, a pigtail-type optical receptacle that can be downsizedwithout reducing the reliability can be provided.

Also, because the optical fiber and the protective member are fixedlybonded to the holder by the first elastic member, the deformation and/ortilting due to an external force of the portion of the optical fiberprotruding from the protective member can be suppressed. Also, theprotrusion from or the reverse retraction into the ferrule of the frontend of the optical fiber due to the application of the external forcecan be suppressed.

Also, by providing the second elastic member, the starting point of thebending when the optical fiber is bent by the handling, etc., can bedistal to the first elastic member. In such a case, by setting thehardness of the second elastic member to be lower than the hardness ofthe first elastic member, the stress that is applied to the protectivemember at the boundary with the second elastic member can be suppressedeven when the optical fiber is bent by handling, etc. Thereby, thedamage of the protective member at the vicinity of the boundary with thefirst elastic member and/or the second elastic member, etc., can besuppressed; and the risk of breakage of the optical fiber can be reducedfurther.

A twenty-fifth invention is the pigtail-type optical receptacle of thetwenty-first invention, wherein a width of the second elastic member ata rear end surface of the holder is wider than a width of the firstelastic member at the rear end surface of the holder.

According to the pigtail-type optical receptacle, the wall thickness ofthe second elastic member can be ensured appropriately regardless of thefinal quality of the width of the first elastic member at the rear endsurface of the holder; and the damage of the second elastic memberitself, etc., can be suppressed even when the optical fiber is bent dueto the stress from the outside, etc.

A twenty-sixth invention is the pigtail-type optical receptacle of thetwenty-first invention, wherein the holder has a first rear end surfaceand a second rear end surface; the second rear end surface is recessedfrontward of the first rear end surface on an outer perimeter side ofthe first rear end surface; and a width in a direction orthogonal to theaxial direction of the second elastic member is narrower than a width inthe direction orthogonal to the axial direction of the first rear endsurface.

According to the pigtail-type optical receptacle, for example, the firstrear end surface can be used as a receiving surface of the bonding agent(the elastic member) when fixedly bonding the optical fiber and theprotective member; and the second rear end surface can be used as apositional alignment surface between the holder and the housing.Thereby, the undesirable flowing of the bonding agent to the positionalalignment surface and the undesirable occurrence of the positional shiftbetween the holder and the housing can be suppressed. Also, theprotective member can be fixedly bonded in a longer region by settingthe length of the portion of the first rear end surface to be longerthan the length of the holder necessary to be held by the housing.Thereby, the deformation and/or the positional shift of the opticalfiber front end portion can be suppressed further.

Also, the flowing of the second elastic member to the second rear endsurface can be suppressed; and the appropriate positional alignment whenassembling is possible.

A twenty-seventh invention is the pigtail-type optical receptacle of thetwenty-first invention, wherein the first elastic member includes aprotrusion protruding outside the holder on the rear end side of theholder; the protrusion covers a corner portion between the rear end ofthe holder and the outer surface of the protective member; and thesecond elastic member covers the protrusion.

According to the pigtail-type optical receptacle, the undesirablebending of the optical fiber locally at the corner portion between therear end of the holder and the outer surface of the protective memberwhen the load is applied by the external force can be suppressed.

A twenty-eighth invention is the pigtail-type optical receptacle of thetwenty-seventh invention, wherein a length in the axial direction of thesecond elastic member is longer than a length in the axial direction ofthe protrusion.

According to the pigtail-type optical receptacle, the wall thickness ofthe second elastic member can be ensured appropriately regardless of thefinal quality of the length in the axial direction of the protrusion;and the damage of the second elastic member itself, etc., can besuppressed even when the optical fiber is bent due to the stress fromthe outside, etc.

A twenty-ninth invention is the pigtail-type optical receptacle of thetwenty-seventh invention, wherein an average tilt angle between an outersurface of the second elastic member and a rear end surface of theholder is not less than an average tilt angle between an outer surfaceof the protrusion and the rear end surface of the holder.

According to the pigtail-type optical receptacle, the wall thickness ofthe second elastic member can be ensured appropriately regardless of thefinal quality of the width of the first elastic member at the rear endsurface of the holder; and the damage of the second elastic memberitself, etc., can be suppressed even when the optical fiber is bent dueto the stress from the outside, etc.

Embodiments of the invention will now be illustrated with reference tothe drawings. Similar components in the drawings are marked with thesame reference numerals; and a detailed description is omitted asappropriate.

First Embodiment

FIG. 1 is a cross-sectional view illustrating a pigtail-type opticalreceptacle according to a first embodiment.

As illustrated in FIG. 1, the pigtail-type optical receptacle(hereinbelow, called the optical receptacle) 10 includes a ferrule 12,an optical fiber 14, a protective member 16, a sleeve 18, a holder 20,and a housing 22.

The ferrule 12 has a tubular configuration that has a through-hole 12 textending in the axial direction. The through-hole 12 t pierces in alinear configuration between a front end 12 a and a rear end 12 b of theferrule 12. The optical fiber 14 is held by the ferrule 12 in a state ofbeing inserted into the through-hole 12 t, and extends outside theferrule 12 from the rear end 12 b side of the ferrule 12. In otherwords, the ferrule 12 holds one end portion of the optical fiber 14.

The optical fiber 14 is inserted into substantially the entirethrough-hole 12 t. A front end 14 a of the optical fiber 14 issubstantially coplanar with the front end 12 a of the ferrule 12. Thefront end 12 a of the ferrule 12 and the front end 14 a of the opticalfiber 14 form the PC (Physical Contact) surface for a plug ferrule (notillustrated) that is inserted into the optical receptacle 10. Theoptical fiber 14 is connected optically to the plug ferrule insertedinto the optical receptacle 10. In the example, the front ends 12 a and14 a are polished into planar configurations. For example, the frontends 12 a and 14 a may be polished into convex spherical configurations,etc.

For example, the end portion of the optical fiber 14 on the sideopposite to the ferrule 12 is connected optically to an optical elementsuch as a semiconductor laser element or the like via an opticalconnector or the like. Thereby, the optical receptacle 10 opticallyconnects the optical element to the inserted plug ferrule via theoptical fiber 14.

For example, the ferrule 12 has a cylindrical configuration. Forexample, the cross section of the optical fiber 14 is a substantiallycircular fine wire configuration. The through-hole 12 t is formed tocorrespond to the cross-sectional configuration of the optical fiber 14.In other words, the cross-sectional configuration of the through-hole 12t is substantially circular. More specifically, the “cross section” hereis a cross section orthogonal to the axial direction of the ferrule 12having the tubular configuration. The exterior configuration of theferrule 12 in the cross section orthogonal to the axial direction is notlimited to a circle and may be a polygon, etc.

For example, the ferrule 12 includes a ceramic, glass, etc. Morefavorably, a zirconia ceramic is used. The optical fiber 14 includes,for example, a core that extends along the axial direction, and claddingthat surrounds the periphery of the core. The refractive index of thecore is higher than the refractive index of the cladding. The core andthe cladding of the optical fiber 14 include, for example, quartz glass.An impurity may be added to the quartz glass. Also, the optical fiber 14is flexible and can be flexed in any direction.

The protective member 16 covers the portion of the optical fiber 14extending outside the ferrule 12. The protective member 16 is flexibleand flexes in any direction with the optical fiber 14. The protectivemember 16 includes, for example, a resin material such as a polyesterelastomer, an acrylate resin, etc. The outer diameter of the protectivemember 16 is, for example, about 0.2 mm to 0.5 mm. The lengths of theportions of the optical fiber 14 and the protective member 16 extendingoutside the ferrule 12 are, for example, about 80 mm. The lengths of theportions of the optical fiber 14 and the protective member 16 extendingoutside the ferrule 12 are not limited thereto and may be any length.

The sleeve 18 engages an outer surface 12 g of the ferrule 12 and ismounted on the front end 12 a side of the ferrule 12. A front end 18 aof the sleeve 18 protrudes frontward of the front end 12 a of theferrule 12. The sleeve 18 surrounds the front end 12 a of the ferrule 12and the front end 14 a of the optical fiber 14 around the axes. Thesleeve 18 holds the plug ferrule inserted from the front end side andallows the optical connection between the optical fiber 14 and the plugferrule.

For example, the sleeve 18 has a cylindrical configuration. The innerdiameter of the sleeve 18 is substantially the same as the outerdiameter of the ferrule 12. Thereby, the sleeve 18 engages the outersurface 12 g of the ferrule 12. The cross-sectional configuration of thesleeve 18 corresponds to the cross-sectional configuration of theferrule 12. For example, in the case where the exterior configuration ofthe ferrule 12 is a quadrilateral, the sleeve 18 is formed in aquadrilateral tubular configuration.

Also, the sleeve 18 has a slit extending in the axial direction. Morespecifically, the cross-sectional configuration of the sleeve 18 is asubstantially C-shaped configuration. The sleeve 18 is a so-called splitsleeve. The slit is provided as necessary and is omissible. The sleeve18 may have a tubular configuration that is continuous in a ringconfiguration around the axis.

The sleeve 18 includes, for example, a resin material, a metal material,a ceramic, etc. More favorably, a zirconia ceramic is used.

The holder 20 engages the outer surface 12 g of the ferrule 12 and holdsthe rear end 12 b side of the ferrule 12. For example, the holder 20 hasa cylindrical configuration. Similarly to the sleeve 18, thecross-sectional configuration of the holder 20 corresponds to thecross-sectional configuration of the ferrule 12. The holder 20 may be atube having any cross-sectional configuration corresponding to theferrule 12. The holder 20 includes, for example, a metal material suchas stainless steel, etc. The material of the holder 20 may be a resinmaterial, a ceramic, etc.

The housing 22 engages an outer surface 20 g of the holder 20 and coversthe ferrule 12 and the sleeve 18. The housing 22 covers the ferrule 12and the sleeve 18 around the axes and protects the ferrule 12 and thesleeve 18 from external forces, etc. Thus, the holder 20 holds theferrule 12 and the sleeve 18 in a state of being housed inside thehousing 22. For example, the housing 22 has a cylindrical configuration.The outer diameter of the holder 20 is larger than the outer diameter ofthe sleeve 18. The inner diameter of the housing 22 is substantially thesame as the outer diameter of the holder 20. The housing 22 engages onlythe outer surface 20 g of the holder 20 without engaging the outersurface of the sleeve 18.

The housing 22 may be a tube having any cross-sectional configurationcorresponding to the holder 20. Also, in the example, the housing 22covers substantially the entire outer surface of the sleeve 18. In otherwords, the entire sleeve 18 is housed inside the housing 22. This is notlimited thereto; for example, a portion of the sleeve 18 may protrudefrontward of the housing 22. It is sufficient for the housing 22 tocover at least a portion of the sleeve 18. The housing 22 includes, forexample, a metal material such as stainless steel, etc. The material ofthe housing 22 may be a resin material, a ceramic, etc.

The through-hole 12 t of the ferrule 12 includes a first region R1 and asecond region R2. The first region R1 is a region where the width in anorthogonal direction orthogonal to the axial direction corresponds tothe width in the orthogonal direction of the optical fiber 14. In otherwords, the first region R1 is a portion of the through-hole 12 t havingsubstantially the same diameter as the outer diameter of the opticalfiber 14. The diameter of the first region R1 is substantially constantalong the axial direction. Also, the first region R1 is continuous withthe front end 12 a of the ferrule 12. The ferrule 12 holds the opticalfiber 14 in the first region R1.

The second region R2 is disposed rearward of the first region R1. Thesecond region R2 is continuous with the first region R1. Also, in theexample, the second region R2 is continuous with the rear end 12 b ofthe ferrule 12. The second region R2 is a region where the width in theorthogonal direction widens toward the rear end 12 b side of the ferrule12. In other words, the second region R2 is a portion of thethrough-hole 12 t in which the diameter widens toward the rear end 12 bside.

In the second region R2, for example, the diameter widens continuouslytoward the rear end 12 b side. For example, the diameter in the secondregion R2 may widen in stages toward the rear end 12 b side. However, bysetting the diameter of the second region R2 to widen continuously, forexample, the front end 14 a of the optical fiber 14 can be insertedeasily into the through-hole 12 t along the tilt of the second region R2when inserting the optical fiber 14 into the through-hole 12 t. Forexample, the manufacturability of the optical receptacle 10 can beimproved.

The holder 20 holds only the portion of the outer surface 12 g of theferrule 12 rearward of the first region R1. In the example, the holder20 holds only the portion of the outer surface 12 g of the ferrule 12opposing the second region R2.

A front end 16 a of the protective member 16 is positioned inside thesecond region R2 of the through-hole 12 t. The protective member 16covers the portion of the optical fiber 14 not held with the ferrule 12.

For example, the holder 20 holds the rear end 12 b side of the ferrule12 by press-fitting. The ferrule 12 is fixed by press-fitting into theholder 20. For example, the housing 22 holds the holder 20 bypress-fitting. The holder 20 is fixed by press-fitting into the housing22. The holding of the ferrule 12 by the holder 20 and the holding ofthe holder 20 by the housing 22 are not limited to press-fitting and maybe bonding, etc. However, by fixing each member by press-fitting asrecited above, the holding force can be increased compared to the caseof fixedly bonding, etc. The members can be held appropriately by asimple configuration. The minimum length in the axial directionnecessary to fix the ferrule 12 in the holder 20 by press-fitting is,for example, about 0.3 mm to 0.5 mm. However, further shortening ispossible by increasing the clamping force by adjusting the outerdiameter of the ferrule 12 and the inner diameter of the holder 20.

A rear end 20 b of the holder 20 is positioned rearward of the rear end12 b of the ferrule 12. The holder 20 surrounds a portion of the opticalfiber 14 and a portion of the protective member 16 around the axes. Theoptical fiber 14 and the protective member 16 further extend outside theholder 20. In other words, the optical fiber 14 and the protectivemember 16 are drawn out rearward from the rear end 20 b of the holder 20in the state of being inserted through the holder 20 and the ferrule 12having the tubular configurations.

The optical receptacle 10 further includes an elastic member 24 (a firstelastic member). The elastic member 24 is filled into the through-hole12 t of the ferrule 12 and into the holder 20. The elastic member 24fixedly bonds the optical fiber 14 and the protective member 16 to theferrule 12 and the holder 20. The elastic member 24 includes, forexample, a resin material such as an epoxy resin, etc. The elasticmember 24 is, for example, a cured bonding agent.

It is sufficient for the elastic member 24 to enter at least a portionof the interior of the through-hole 12 t and at least a portion of theinterior of the holder 20. The entireties of the interiors of thethrough-hole 12 t and the holder 20 may not be always be filled with theelastic member 24. For example, “filling” also includes the case where avoid or the like is partially included.

An inner perimeter surface 20 n of the holder 20 includes a first innerperimeter portion IS1 and a second inner perimeter portion IS2. Thefirst inner perimeter portion IS1 engages the outer surface 12 g of theferrule 12. The second inner perimeter portion IS2 is positionedrearward of the first inner perimeter portion IS1, protrudes inward fromthe first inner perimeter portion IS1, and surrounds a portion of theoptical fiber 14 and a portion of the protective member 16 around theaxes.

The inner diameter of the portion of the first inner perimeter portionIS1 of the holder 20 is substantially the same as the outer diameter ofthe ferrule 12. On the other hand, the inner diameter of the portion ofthe second inner perimeter portion IS2 of the holder 20 is smaller thanthe outer diameter of the ferrule 12. Accordingly, the second innerperimeter portion IS2 is positioned rearward of the rear end 12 b of theferrule 12.

For example, the inner diameter of the portion of the second innerperimeter portion IS2 is set to a value that is larger than the outerdiameter of the protective member 16 and smaller than the outer diameterof the ferrule 12. For example, the inner diameter of the portion of thesecond inner perimeter portion IS2 is smaller than the opening diameteron the rear end 12 b side of the through-hole 12 t that widens in thesecond region R2.

A gap SP in the axial direction is provided between the rear end 12 b ofthe ferrule 12 and the second inner perimeter portion IS2. The elasticmember 24 is filled also into the gap SP. For example, the distance inthe axial direction of the gap SP is longer than the outer diameter ofthe optical fiber 14. For example, the distance in the axial directionof the gap SP is not less than about 0.125 mm and not more than about0.2 mm. In other words, the distance in the axial direction of the gapSP is the distance in the axial direction between the second innerperimeter portion IS2 and the rear end 12 b of the ferrule 12. In otherwords, the outer diameter of the optical fiber 14 is the length in adirection orthogonal to the axial direction of the optical fiber 14.

The holder 20 has a first rear end surface BS1 and a second rear endsurface BS2. The second rear end surface BS2 is recessed frontward ofthe first rear end surface BS1 on the outer perimeter side of the firstrear end surface BS1. In the example, the rear end 20 b of the holder 20is the first rear end surface BS1. For example, the first rear endsurface BS1 has a ring configuration surrounding the opening end on therear end 20 b side of the holder 20 having the tubular configuration.For example, the second rear end surface BS2 has a ring configurationsurrounding the first rear end surface BS1 in the state in which theholder 20 is viewed along the axial direction. The first rear endsurface BS1 and the second rear end surface BS2 are, for example, planesorthogonal to the axial direction. As described above, the innerperimeter surface 20 n of the holder 20 protrudes on the inner side atthe rear end vicinity of the inner perimeter surface 20 n. Thereby, thesurface areas of the first rear end surface BS1 and the second rear endsurface BS2 can be increased.

The holder 20 includes a chamfer portion 20 c between the first rear endsurface BS1 (the rear end surface) and the second inner perimeterportion IS2 (the inner perimeter surface 20 n). In other words, thediameter of the opening on the rear end 20 b side of the holder 20widens toward the rear end 20 b side. The chamfer portion 20 c may be aso-called C-surface in which the corner between the first rear endsurface BS1 and the second inner perimeter portion IS2 is polished intoa linear configuration, or a so-called R-surface in which the cornerbetween the first rear end surface BS1 and the second inner perimeterportion IS2 is rounded.

The elastic member 24 includes a protrusion 24 p that protrudes outsidethe holder 20 on the rear end 20 b side of the holder 20 and covers thecorner portion between the rear end 20 b of the holder 20 and the outersurface of the protective member 16. For example, the outer surface ofthe protrusion 24 p is concave toward the corner portion side and has aconcave curved-surface configuration smoothly connecting the rear end 20b of the holder 20 and the outer surface of the protective member 16.

The outer surface 12 g of the ferrule 12 includes a first contactportion CP1 contacting the inner perimeter surface 20 n of the holder20. The outer surface 20 g of the holder 20 includes a second contactportion CP2 contacting the inner perimeter surface of the housing 22. Anintermediate point m2 in the axial direction of the second contactportion CP2 is positioned rearward of an intermediate point m1 in theaxial direction of the first contact portion CP1.

In the optical receptacle 10 according to the embodiment as describedabove, because the ferrule 12 and at least a portion of the sleeve 18are housed inside the housing 22, the lengths of the ferrule 12 and/orthe housing 22 can be shortened compared to a configuration in which therear end 12 b of the ferrule 12 protrudes rearward of the housing 22.Also, the holder 20 holds the portion of the outer surface 12 g of theferrule 12 rearward of the first region R1. Thereby, for example, anundesirable concentration of an external force in the optical fiber 14at the boundary portion between the first region R1 holding the opticalfiber 14 and the second region R2 not holding the optical fiber 14 canbe suppressed even in the case where the diameter of the ferrule 12contracts due to the press-fitting of the holder 20 into the housing 22and the press-fitting of the ferrule 12 into the holder 20. Accordingly,the optical receptacle 10 in which downsizing is possible can beprovided without causing the decrease of the reliability.

Also, in the optical receptacle 10, the front end 16 a of the protectivemember 16 is positioned inside the second region R2 of the through-hole12 t. Thereby, the length of the portion of the optical fiber 14protruding from the protective member 16 can be shortened as much aspossible. For example, the flexing of the optical fiber 14 can besuppressed; and the optical fiber 14 can be inserted easily into thethrough-hole 12 t of the ferrule 12. For example, the manufacturabilityof the optical receptacle 10 can be improved.

In the optical receptacle 10, the holder 20 holds the rear end 12 b sideof the ferrule 12 by press-fitting. Thereby, the holding force can beincreased; and the ferrule 12 can be held appropriately by a simpleconfiguration. In the optical receptacle 10, the optical fiber 14 andthe protective member 16 further extend outside the holder 20 and arefixedly bonded to the holder 20 by the elastic member 24. Thereby,deformation and/or tilting due to an external force of the portion ofthe optical fiber 14 protruding from the protective member 16 can besuppressed. Also, the protrusion from or the reverse retraction into thefront end 12 a of the ferrule 12 of the front end 14 a of the opticalfiber 14 due to the application of the external force can be suppressed.

In the optical receptacle 10, the elastic member 24 is filled also intothe gap SP between the second inner perimeter portion IS2 and the rearend 12 b of the ferrule 12. Thereby, the deformation and/or thepositional shift of the front end portion of the optical fiber 14 due tothe external force can be suppressed further.

In the optical receptacle 10, the holder 20 has the first rear endsurface BS1 and the second rear end surface BS2. Thereby, for example,by using the first rear end surface BS1 as the receiving surface of thebonding agent used to form the elastic member 24, the undesirableflowing of the bonding agent to the second rear end surface BS2 can besuppressed. Then, the undesirable occurrence of positional shift betweenthe holder 20 and the housing 22 can be suppressed by using the secondrear end surface BS2 as the positional alignment surface whenpress-fitting the holder 20 into the housing 22 and by press-fittinginto the housing 22 by pressing the second rear end surface BS2.

For example, in the case where the coating of the bonding agent and thepositional alignment of the holder 20 are to be performed in the sameplane, there is a possibility that the bonding agent may undesirablyflow to the positional alignment surface; and the holder 20 may beundesirably press-fitted deeply into the housing 22 due to the amount ofthe cured bonding agent. By providing the first rear end surface BS1 andthe second rear end surface BS2, such positional shift can besuppressed; and the positional precision between the holder 20 and thehousing 22 can be increased.

Also, by providing the gap SP, the distance between the second rear endsurface BS2 which is the positional alignment surface and the front end12 a of the ferrule 12 which is the PC-surface can be determined moreaccurately. For example, in the case where there is no gap SP and thesecond inner perimeter portion IS2 and the rear end 12 b of the ferrule12 contact each other, the length from the second rear end surface BS2to the front end 12 a of the ferrule 12 undesirably changes due to thefinal quality (the error, the fluctuation, etc.) of the total lengthdimension of the ferrule 12 and/or the thickness dimension of the holder20. Conversely, by providing the gap SP as in the optical receptacle 10,the length from the second rear end surface BS2 to the front end 12 a ofthe ferrule 12 can be determined more accurately without being dependenton the final quality of the parts. Thereby, an increase of thereliability and/or the productivity of the optical receptacle 10 can berealized.

In the case where the gap SP is not provided, there is a risk that theferrule 12 may be fixed obliquely due to the final quality of theperpendicularity of the second inner perimeter portion IS2 and/or therear end 12 b of the ferrule 12, etc.; the ferrule 12 may be chipped;and the holder 20 may undesirably deform. By providing the gap SP in theoptical receptacle 10, the oblique press-fitting of the ferrule 12, thedamage and deformation of the parts, etc., can be suppressed regardlessof the final quality of the parts.

The error of the total length dimension of the ferrule 12 is, forexample, about ±0.05 mm (a range of 0.1 mm). The error of the thicknessdimension of the holder 20 is, for example, about ±0.05 mm (a range of0.1 mm). In such a case, it is favorable for the distance in the axialdirection of the gap SP to be about 0.2 mm. Thus, the distance in theaxial direction of the gap SP is set to be longer than the outerdiameter of the optical fiber 14. The distance in the axial direction ofthe gap SP is set to be not less than about 0.125 mm and not more thanabout 0.2 mm. Thereby, the reliability and/or the productivity of theoptical receptacle 10 can be increased further.

Also, the length where the protective member 16 is fixedly bonded can belonger by setting the length of the portion of the first rear endsurface BS1 to be longer than the length necessary for the holder 20 tobe held by the housing 22 (the length necessary for the press-fitting).Thereby, the deformation and/or the positional shift of the front endportion of the optical fiber 14 can be suppressed further.

In the optical receptacle 10, by providing the chamfer portion 20 cbetween the rear end surface and the inner perimeter surface of theholder 20, the optical fiber 14 can be inserted easily into the holder20; and the manufacturability can be improved. Also, when coating abonding agent on the first rear end surface BS1, the chamfer portion 20c can be used as a bonding agent reservoir; and the undesirable flowingof the bonding agent to the second rear end surface BS2 (the positionalalignment surface) can be suppressed further.

In the optical receptacle 10, the elastic member 24 includes theprotrusion 24 p. Thereby, the undesirable bending of the optical fiber14 locally at the corner portion between the rear end 20 b of the holder20 and the outer surface of the protective member 16 when the load isapplied by the external force can be suppressed. For example, thestarting point of the bending of the optical fiber 14 can be distal tothe boundary portion between the first region R1 and the second regionR2.

In the optical receptacle 10, the housing 22 holds the holder 20 bypress-fitting. Thereby, the holding force can be increased; and theholder 20 can be held appropriately by a simple configuration.

In the optical receptacle 10, the intermediate point m2 of the secondcontact portion CP2 of the holder 20 is positioned rearward of theintermediate point m1 of the first contact portion CP1 of the ferrule12. Thereby, for example, even in the case where the holder 20 ispress-fitted into the housing 22, etc., the clamping force due to thepress-fitting can be dispersed over a wide region by the second contactportion CP2; and the undesirable concentration of the external force inthe optical fiber 14 at the boundary portion between the first region R1and the second region R2 can be suppressed further.

FIG. 2A to FIG. 2C are cross-sectional views illustrating specificexamples of the ferrule according to the first embodiment.

In the example as illustrated in FIG. 2A, the change of the diameter(the width in the orthogonal direction) of the through-hole 12 t in thesecond region R2 has a linear configuration. The inner perimeter surfaceof the second region R2 of the through-hole 12 t has a linearconfiguration in a cross section parallel to the central axis of thethrough-hole 12 t (the cross section illustrated in FIG. 2A). Thus, thechange of the diameter in the second region R2 has, for example, alinear configuration. A spread angle θ of the diameter of thethrough-hole 12 t in the second region R2 is, for example, not less than60° and not more than 90°. For example, the spread angle θ is set to60°; and in the case where the diameter of the through-hole 12 t in thefirst region R1 is set to 0.8 mm, the length in the axial direction ofthe second region R2 is about 0.6 mm.

In such a case, when the inner diameter of the ferrule 12 contracts dueto the press-fitting, etc., stress is applied to the portion of theoptical fiber 14 inserted into the through-hole 12 t in the first regionR1; but the stress due to the contraction substantially is not appliedto the portion in the second region R2. Therefore, the differencebetween the stresses applied to the optical fiber 14 at the boundaryportion between the first region R1 and the second region R2 is large.

Accordingly, in the case where the ferrule 12 illustrated in FIG. 2A isused, as recited above, the holder 20 is set to hold the portion of theouter surface 12 g of the ferrule 12 rearward of the first region R1.Thereby, the contraction of the diameter at the portion in the firstregion R1 can be suppressed; and the stress difference that is generatedat the boundary portion between the first region R1 and the secondregion R2 can be relaxed. The undesirable concentration of the externalforce in the optical fiber 14 at the boundary portion between the firstregion R1 and the second region R2 can be suppressed.

In the example as illustrated in FIG. 2B, the change of the diameter ofthe through-hole 12 t in the second region R2 has a curved configurationthat is convex toward the central axis side of the through-hole 12 t.The inner perimeter surface of the second region R2 of the through-hole12 t has a convex curved configuration in a cross section parallel tothe central axis of the through-hole 12 t. For example, the innerperimeter surface of the second region R2 of the through-hole 12 tsmoothly connects the inner perimeter surface of the first region R1 ofthe through-hole 12 t and the rear end surface of the ferrule 12. Thus,for example, the change of the diameter in the second region R2 may havea convex curved configuration.

In such a case, the stress that is applied to the optical fiber 14 dueto the contraction of the inner diameter of the ferrule 12 changesgradually according to the curved surface of the inner perimeter surfaceof the second region R2. In other words, an abrupt change of the stressapplied to the optical fiber 14 at the boundary portion between thefirst region R1 and the second region R2 can be suppressed; and thestress difference at the boundary portion between the first region R1and the second region R2 can be relaxed. Accordingly, the undesirableconcentration of the external force in the optical fiber 14 at theboundary portion between the first region R1 and the second region R2can be suppressed further.

In the example as illustrated in FIG. 2C, the through-hole 12 t of theferrule 12 further includes a third region R3 disposed rearward of thesecond region R2. The third region R3 is continuous with the secondregion R2. Also, in the example, the third region R3 is continuous withthe rear end 12 b of the ferrule 12.

Similarly to the example of FIG. 2B, the change of the diameter of thethrough-hole 12 t in the second region R2 has a curved configurationthat is convex toward the central axis side of the through-hole 12 t. Onthe other hand, the change of the diameter of the through-hole 12 t inthe third region R3 has a linear configuration. In the third region R3,the diameter of the through-hole 12 t increases continuously in a linearconfiguration toward the rear end 12 b side. In other words, in theexample, the configuration of the second region R2 is a configuration inwhich the intersection portion between the first region R1 and the thirdregion R3 having the linear configurations is rounded.

Thus, in the through-hole 12 t, the third region R3 where the diameterchanges in the linear configuration may be further provided rearward ofthe second region R2 where the diameter changes in the convex curvedconfiguration. Even in such a case, similarly to the example of FIG. 2B,the abrupt change of the stress applied to the optical fiber 14 at theboundary portion between the first region R1 and the second region R2can be suppressed; and the stress difference at the boundary portionbetween the first region R1 and the second region R2 can be relaxed. Theundesirable concentration of the external force in the optical fiber 14at the boundary portion between the first region R1 and the secondregion R2 can be suppressed further. It is sufficient for a region wherethe diameter changes in a convex curved configuration to be provided atleast directly after the first region R1. Also, in the case where thethird region R3 is provided, the front end 16 a of the protective member16 may be positioned inside the third region R3 of the through-hole 12t. Even in such a case, similarly to the case where the front end 16 ais positioned in the second region R2, the length of the portion of theoptical fiber 14 protruding from the protective member 16 can beshortened as much as possible. The flexing of the optical fiber 14 canbe suppressed; and the optical fiber 14 can be inserted easily into thethrough-hole 12 t of the ferrule 12. The manufacturability of theoptical receptacle 10 can be improved.

In the case where the ferrule 12 includes a ceramic, the configurationsof the through-holes 12 t of the examples illustrated in FIG. 2A to FIG.2C can be formed by, for example, inserting pin-shaped moldscorresponding to the configurations of the through-holes 12 t intoblock-shaped ceramics before firing.

FIG. 3 is a cross-sectional view illustrating a modification of thepigtail-type optical receptacle according to the first embodiment.

In the optical receptacle 10 a as illustrated in FIG. 3, the holder 20holds the portion of the outer surface 12 g of the ferrule 12 rearwardof the first region R1 and further holds a portion of the outer surface12 g opposing the first region R1. Components that are substantially thesame functionally and configurationally as those of the embodimentrecited above are marked with the same reference numerals; and adetailed description is omitted.

For example, as illustrated in FIG. 2B and FIG. 2C, in the case wherethe change of the diameter of the through-hole 12 t in the second regionR2 has a convex curved configuration, the stress difference at theboundary portion between the first region R1 and the second region R2can be relaxed appropriately even by only the configuration of thethrough-hole 12 t. Accordingly, in such a case, the holder 20 mayfurther hold the portion opposing the first region R1. In the opticalreceptacle 10 a as well, downsizing is possible without causing thedecrease of the reliability. However, the ferrule 12 in which thediameter of the through-hole 12 t changes in the convex curvedconfiguration may be used; and only the portion of the ferrule 12rearward of the first region R1 may be held by the holder 20. Thereby,the stress difference at the boundary portion between the first regionR1 and the second region R2 can be relaxed more appropriately. Theundesirable concentration of the external force in the optical fiber 14at the boundary portion between the first region R1 and the secondregion R2 can be suppressed further.

FIG. 4 is a cross-sectional view illustrating a modification of thepigtail-type optical receptacle according to the first embodiment.

In the optical receptacle 10 b as illustrated in FIG. 4, a rear end 22 bof the housing 22 is positioned rearward of the rear end 20 b of theholder 20 and the protrusion 24 p of the elastic member 24. In otherwords, in the optical receptacle 10 b, the housing 22 further covers theholder 20 around the axis and further covers the protrusion 24 p of theelastic member 24 around the axis.

In the optical receptacle 10 b, for example, the protrusion 24 p of theelastic member 24 can be protected by the housing 22. The application ofan external force to the protrusion 24 p can be suppressed. Theconcentration of the external force at the boundary portion between thefirst region R1 and the second region R2 of the optical fiber 14 can besuppressed further. The optical fiber 14 can be protected moreappropriately from the external force, etc.

Second Embodiment

FIG. 5 is a cross-sectional view illustrating a pigtail-type opticalreceptacle according to a second embodiment.

In the optical receptacle 100 as illustrated in FIG. 5, an outer surface120 g of a holder 120 includes a first outer perimeter portion OS1 and asecond outer perimeter portion OS2.

The first outer perimeter portion OS1 is held by the housing 22. Theouter diameter of the first outer perimeter portion OS1 of the holder120 is substantially the same as the inner diameter of the housing 22.For example, the holder 120 is held by the housing 22 by press-fittingthe portion of the first outer perimeter portion OS1 into the housing22.

The second outer perimeter portion OS2 is provided at the front endportion of the holder 120. For example, the second outer perimeterportion OS2 is provided frontward of the first outer perimeter portionOS1, is continuous with the first outer perimeter portion OS1, and iscontinuous with a front end 120 a of the holder 120. The second outerperimeter portion OS2 is recessed inward from the first outer perimeterportion OS1. The outer diameter of the second outer perimeter portionOS2 of the holder 120 is smaller than the outer diameter of the firstouter perimeter portion OS1. The first outer perimeter portion OS1 ispositioned rearward of the first region R1. Accordingly, the housing 22engages the outer surface 120 g of the holder 120 rearward of the firstregion R1.

Thus, in the optical receptacle 100, by setting the outer diameter ofthe front end portion of the holder 120 to be small, the portion of theholder 120 held by the housing 22 can be shifted rearward. Thereby, theundesirable concentration of the external force in the optical fiber 14at the boundary portion between the first region R1 and the secondregion R2 can be suppressed further.

Also, in the optical receptacle 100, the holder 120 holds only theportion of the ferrule 12 rearward of the first region R1. Thereby, theundesirable concentration of the external force in the optical fiber 14at the boundary portion between the first region R1 and the secondregion R2 can be suppressed further.

Further, in the optical receptacle 100, the holder 120 holds the ferrule12 only at the portion of the second outer perimeter portion OS2. Inother words, the periphery of the ferrule 12 is not press-fitted intothe housing 22. Thereby, for example, the undesirable transfer, to theboundary portion between the first region R1 and the second region R2 ofthe optical fiber 14 via the holder 120, of the clamping force due tothe press-fitting of the holder 120 into the housing 22 can besuppressed. Accordingly, the undesirable concentration of the externalforce in the optical fiber 14 at the boundary portion between the firstregion R1 and the second region R2 can be suppressed further. FIG. 6 isa cross-sectional view illustrating a modification of the pigtail-typeoptical receptacle according to the second embodiment.

In the optical receptacle 100 a as illustrated in FIG. 6, the holder 120holds the portion of the outer surface 12 g of the ferrule 12 rearwardof the first region R1 and further holds the portion of the outersurface 12 g opposing the first region R1. In the optical receptacle 100a, the first outer perimeter portion OS1 of the holder 120 is positionedrearward of the first region R1.

Thus, in the case where the first outer perimeter portion OS1 and thesecond outer perimeter portion OS2 are provided in the holder 120, it issufficient for at least the first outer perimeter portion OS1 to bepositioned rearward of the first region R1; and the holder 120 mayfurther hold the portion of the ferrule 12 opposing the first region R1.

In other words, it is sufficient for at least the periphery of theboundary portion between the first region R1 and the second region R2not to be press-fitted into the housing 22. Even in such a case, theundesirable transfer, to the boundary portion between the first regionR1 and the second region R2 of the optical fiber 14 via the holder 120,of the clamping force due to the press-fitting of the holder 120 intothe housing 22 can be suppressed.

However, as illustrated in FIG. 5, the first outer perimeter portion OS1and the second outer perimeter portion OS2 may be provided in the holder120; and only the portion of the ferrule 12 rearward of the first regionR1 may be held by the holder 120. Thereby, the undesirable transfer tothe optical fiber 14 of the clamping force due to the press-fitting canbe suppressed further. The undesirable concentration of the externalforce in the optical fiber 14 at the boundary portion between the firstregion R1 and the second region R2 can be suppressed more appropriately.

FIG. 7 is a cross-sectional view illustrating a modification of thepigtail-type optical receptacle according to the second embodiment.

In the optical receptacle 100 b as illustrated in FIG. 7, an innersurface 122 n of a housing 122 includes a first inner perimeter portion122 a and a second inner perimeter portion 122 b. The first innerperimeter portion 122 a engages the outer surface 20 g of the holder 20.The inner diameter of the first inner perimeter portion 122 a issubstantially the same as the outer diameter of the holder 20. Forexample, the housing 122 is mounted to the holder 20 by press-fittingthe first inner perimeter portion 122 a into the holder 20. For example,the first inner perimeter portion 122 a is formed in a ringconfiguration around the entire perimeter of the inner surface 122 n ofthe housing 122. For example, multiple first inner perimeter portions122 a may be provided to be arranged discretely along the innerperimeter of the housing 122.

The second inner perimeter portion 122 b is provided frontward of thefirst inner perimeter portion 122 a. The second inner perimeter portion122 b widens outward from the first inner perimeter portion 122 a. Theinner diameter of the second inner perimeter portion 122 b is largerthan the inner diameter of the first inner perimeter portion 122 a.

The first inner perimeter portion 122 a is positioned rearward of thefirst region R1. Accordingly, the housing 122 engages the outer surface20 g of the holder 20 rearward of the first region R1.

Thus, in the optical receptacle 100 b, by setting the inner diameter ofthe second inner perimeter portion 122 b of the housing 122 to be large,the first inner perimeter portion 122 a where the holder 20 is held bythe housing 122 can be shifted rearward. Thereby, similarly to theoptical receptacle 100 described in reference to FIG. 5, etc., theundesirable concentration of the external force in the optical fiber 14at the boundary portion between the first region R1 and the secondregion R2 can be suppressed.

In FIG. 7, the holder 20 holds the first region R1 and the second regionR2. Even in the case where the housing 122 is used, the holder 20 mayhold only the portion of the ferrule 12 rearward of the first region R1.Thereby, the undesirable transfer to the optical fiber 14 of theclamping force due to the press-fitting can be suppressed further.

FIG. 8A and FIG. 8B are cross-sectional views illustrating modificationsof the pigtail-type optical receptacle according to the secondembodiment.

In the housing 122 of an optical receptacle 100 c as illustrated in FIG.8A, the second inner perimeter portion 122 b is connected to the firstinner perimeter portion 122 a via a tilted surface 122 c. In the housing122 of an optical receptacle 100 d as illustrated in FIG. 8B, the secondinner perimeter portion 122 b is connected to the first inner perimeterportion 122 a via a curved surface 122 d. For example, the curvedsurface 122 d has a concave curved-surface configuration that issmoothly continuous with the second inner perimeter portion 122 b.

Thus, it is favorable for the first inner perimeter portion 122 a andthe second inner perimeter portion 122 b to be connected smoothly by thetilted surface 122 c or the curved surface 122 d. Thereby, the housing122 can be formed easily even in the case where the first innerperimeter portion 122 a and the second inner perimeter portion 122 b areprovided in the inner surface 122 n of the housing 122. For example, themanufacturability of the housing 122 can be improved; and themanufacturing cost of the optical receptacles 100 c and 100 d can besuppressed.

Third Embodiment

FIG. 9 is a cross-sectional view illustrating a pigtail-type opticalreceptacle according to a third embodiment.

In the optical receptacle 200 as illustrated in FIG. 9, a housing 222 ismounted on the front end side of a holder 220.

The holder 220 includes a mounting portion 220 a for mounting thehousing 222. The mounting portion 220 a is provided at the front endportion of the holder 220. The housing 222 includes a mounted portion222 a where the housing 222 is mounted to the mounting portion 220 a.The mounted portion 222 a is provided at the rear end portion of thehousing 222. The mounting portion 220 a and the mounted portion 222 ahave tubular configurations. The mounted portion 222 a engages the outerside of the mounting portion 220 a. Thereby, the housing 222 is mountedon the front end side of the holder 220.

The holder 220 includes a flange 220 f. The flange 220 f is providedfrontward of the second region R2. The front end of the flange 220 f ispositioned frontward of the front end of the second region R2. Also, theflange 220 f protrudes outward from the housing 222 mounted to themounting portion 220 a. For example, the flange 220 f is used in thepositional alignment of the optical receptacle 200.

The mounting portion 220 a is provided frontward of the flange 220 f.Accordingly, the housing 222 is mounted to the holder 220 frontward ofthe flange 220 f.

In the optical receptacle 200, the flange 220 f that protrudes outwardfrom the housing 222 is included; and the housing 222 is mounted to theholder 220 frontward of the flange 220 f. Thereby, for example, comparedto the case where the housing 222 is mounted to the holder 220 on therear end side of the flange 220 f, the lengths of the ferrule 12, theholder 220, and the housing 222 can be shortened while suppressing theundesirable concentration, of the external force caused by mounting thehousing 222, in the optical fiber 14 at the boundary portion between thefirst region R1 holding the optical fiber 14 and the second region R2not holding the optical fiber 14. Accordingly, a pigtail-type opticalreceptacle 200 that can be downsized without causing the decrease of thereliability can be provided.

In FIG. 9, the holder 220 holds the first region R1 and the secondregion R2. Even in a configuration in which the housing 222 is mounted,the holder 220 may hold only the portion of the ferrule 12 rearward ofthe first region R1. Thereby, the undesirable transfer to the opticalfiber 14 of the clamping force due to the press-fitting can besuppressed further.

FIG. 10A and FIG. 10B are cross-sectional views illustratingmodifications of the pigtail-type optical receptacle according to thethird embodiment.

In an optical receptacle 200 a as illustrated in FIG. 10A, the housing222 is mounted on the front end side of the holder 220 by the mountedportion 222 a engaging the inner side of the mounting portion 220 a.Thus, the mounted portion 222 a may engage the outer side of themounting portion 220 a or may engage the inner side of the mountingportion 220 a. The configurations of the mounting portion 220 a and themounted portion 222 a are not limited to those recited above; and anyconfiguration in which the housing 222 is mountable to the front endside of the holder 220 may be used.

In an optical receptacle 200 b as illustrated in FIG. 10B, the mountingportion 220 a extends further frontward compared to the mounting portion220 a of the optical receptacle 200 shown in FIG. 9. Thus, the positionof the mounting portion 220 a (the mounting position of the housing 222)may be any position frontward of the flange 220 f.

Fourth Embodiment

FIG. 11 is a cross-sectional view illustrating a pigtail-type opticalreceptacle according to a fourth embodiment. As illustrated in FIG. 11,the optical receptacle 300 includes an elastic member 302 (a secondelastic member).

Other than the elastic member 302, the configuration of the opticalreceptacle 300 is similar to the configuration of the optical receptacle10 of the first embodiment; and a detailed description is thereforeomitted. Other than the elastic member 302, the configuration of theoptical receptacle 300 is not limited to the configuration of theoptical receptacle 10 and may be similar to any of the opticalreceptacles 10 a, 10 b, 100, 100 a to 100 d, 200, 200 a, and 200 bdescribed in the embodiments recited above.

FIG. 12 is a partial cross-sectional view illustrating an enlargedportion of the pigtail-type optical receptacle according to the fourthembodiment.

As illustrated in FIG. 11 and FIG. 12, the elastic member 302 covers thecorner portion between the rear end 20 b of the holder 20 and the outersurface of the protective member 16. In the case where the elasticmember 24 includes the protrusion 24 p, the elastic member 302 coversthe protrusion 24 p. For example, the elastic member 302 covers theentire outer surface of the protrusion 24 p. In other words, the elasticmember 302 covers the boundary portion between the elastic member 24 andthe protective member 16.

The hardness of the elastic member 302 is lower than the hardness of theelastic member 24. In other words, the elastic modulus of the elasticmember 302 is smaller than the elastic modulus of the elastic member 24.The hardness of the elastic member 24 is higher than the hardness of theprotective member 16. The hardness of the elastic member 302 is, forexample, about the same as the hardness of the protective member 16. Thehardness of the elastic member 302 is, for example, not less than 0.8times and not more than 1.2 times the hardness of the protective member16. The hardness of the protective member 16 is, for example, aboutShore D20-30. In such a case, similarly, the hardness of the elasticmember 302 is about Shore D20-30.

As described above, the protective member 16 includes a resin materialsuch as a polyester elastomer, an acrylate resin, etc. As describedabove, the elastic member 24 includes a resin material such as an epoxyresin, etc. The elastic member 302 includes, for example, a resinmaterial such as a polyester resin, an acrylic resin, a silicone resin,etc. The elastic member 24 and the elastic member 302 include, forexample, a resin bonding agent. In such a case, the hardness of theelastic member 24 and the hardness of the elastic member 302 arehardnesses after the curing of the bonding agent (after completelycuring).

A width W2 of the elastic member 302 at the first rear end surface BS1(the rear end surface) of the holder 20 is wider than a width W1 of theelastic member 24 at the first rear end surface BS1 of the holder 20.More specifically, the width W1 and the width W2 are widths (lengths) ina direction orthogonal to the axial direction. Also, the width W2 of theelastic member 302 in the direction orthogonal to the axial direction isnarrower than a width Wbs of the first rear end surface BS1 in thedirection orthogonal to the axial direction. The width W1 of the elasticmember 24 is not more than the width (the outer diameter) of the chamferportion 20 c of the holder 20 in the direction orthogonal to the axialdirection. In other words, the elastic member 24 does not spread outwardfrom the chamfer portion 20 c.

A length L2 in the axial direction of the elastic member 302 is longerthan a length L1 in the axial direction of the protrusion 24 p of theelastic member 24. For example, the length L2 in the axial direction ofthe elastic member 302 is not less than 2 times and not more than 4times the length L1 in the axial direction of the protrusion 24 p of theelastic member 24.

An average tilt angle θ2 between the outer surface of the elastic member302 and the first rear end surface BS1 of the holder 20 is not less thanan average tilt angle θ1 between the outer surface of the protrusion 24p and the first rear end surface BS1 of the holder 20.

Here, more specifically, the average tilt angle θ1 of the outer surfaceof the protrusion 24 p is, for example, the minor angle of the anglesbetween an imaginary line VL1 and directions orthogonal to the axialdirection. The imaginary line VL1 is, for example, an imaginary lineconnecting a front end portion 24 a of the outer surface of theprotrusion 24 p in a cross section parallel to the axial direction and arear end portion 24 b of the outer surface of the protrusion 24 p in thecross section. Similarly, the average tilt angle θ2 of the outer surfaceof the elastic member 302 is, for example, the minor angle of the anglesbetween an imaginary line VL2 and directions orthogonal to the axialdirection. The imaginary line VL2 is, for example, an imaginary lineconnecting a front end portion 302 a of the outer surface of the elasticmember 302 in a cross section parallel to the axial direction and a rearend portion 302 b of the outer surface of the elastic member 302 in thecross section.

In FIG. 12, the outer surface of the elastic member 302 and the outersurface of the protrusion 24 p are illustrated as tilted surfaces havinglinear configurations for convenience. The outer surface of the elasticmember 302 and the outer surface of the protrusion 24 p are not limitedthereto and may have, for example, a convex curved-surfaceconfiguration, a concave curved-surface configuration, etc. Theconfiguration of the outer surface of the elastic member 302 and theconfiguration of the outer surface of the protrusion 24 p may be anyconfiguration.

When bending the optical fiber 14 in handling, etc., stress is appliedeasily to the optical fiber 14 at the base portion of the optical fiber14 protruding from the holder 20 (the rear end portion of the holder20); and breakage of the optical fiber 14 occurs easily. Therefore, theoptical fiber 14 is coated with the protective member 16 to relax thestress on the optical fiber 14. Further, a protective member such as atube (e.g., referring to JP-A 2013-200352 (Kokai)), a boot (e.g.,referring to JP-A 2016-224346 (Kokai)), etc., may be mounted atfundamental portions.

However, in the case where a protective member such as a tube, a boot,or the like is mounted, the holder 20, etc., must be set to be longer bythe amount covered with the protective member; the length in the axialdirection of the optical receptacle undesirably lengthens; and a largersize of the product is undesirably caused. Therefore, in the case wheredownsizing is necessary, the optical fiber 14 is mounted in the productinterior in the state of being protected by only the protective member16.

The protective member 16 is fixedly bonded to the holder 20 by theelastic member 24. Generally, the hardness of the protective member 16is lower than the hardness of the elastic member 24. Therefore, when theoptical fiber 14 is bent in handling, etc., the stress generated at theboundary between the protective member 16 and the elastic member 24 ishigh; in the worst case, there is a possibility that the protectivemember 16 may be damaged; and the protection function of the opticalfiber 14 may undesirably decrease.

Conversely, by providing the elastic member 302 in the opticalreceptacle 300 according to the embodiment, the starting point of thebending when the optical fiber 14 is bent in handling, etc., can bedistal to the elastic member 24. In such a case, by setting the hardnessof the elastic member 302 to be lower than the hardness of the elasticmember 24, the stress that is applied to the protective member 16 at theboundary with the elastic member 302 can be suppressed even when theoptical fiber 14 is bent in handling, etc. Thereby, the damage of theprotective member 16 at the boundary vicinity with the elastic member 24and/or the elastic member 302, etc., can be suppressed; and the risk ofbreakage of the optical fiber 14 can be reduced further. Also, thelarger size of the product also can be suppressed compared to the casewhere a protective member such as a tube, a boot, or the like isprovided.

Also, in the optical receptacle 300, the width W2 of the elastic member302 at the first rear end surface BS1 of the holder 20 is wider than thewidth W1 of the elastic member 24 at the first rear end surface BS1 ofthe holder 20. Thereby, the wall thickness of the elastic member 302 canbe ensured appropriately regardless of the final quality of the width W1of the elastic member 24 at the rear end surface of the holder 20; andthe damage of the elastic member 302 itself, etc., can be suppressedeven when the optical fiber 14 is bent by stress from the outside, etc.

In the optical receptacle 300, the width W2 of the elastic member 302 inthe direction orthogonal to the axial direction is narrower than thewidth Wbs of the first rear end surface BS1 in the direction orthogonalto the axial direction. Thereby, the flow of the elastic member 302 tothe second rear end surface BS2 can be suppressed; and the appropriatepositional alignment when assembling is possible.

In the optical receptacle 300, the length L2 in the axial direction ofthe elastic member 302 is longer than the length L1 in the axialdirection of the protrusion 24 p. Thereby, the wall thickness of theelastic member 302 can be ensured appropriately regardless of the finalquality of the length in the axial direction of the protrusion 24 p; andthe damage of the elastic member 302 itself, etc., can be suppressedeven when the optical fiber 14 is bent by stress from the outside, etc.

The length L2 of the elastic member 302 is, for example, not less than 2times the length L1 of the protrusion 24 p. Thereby, the damage of theelastic member 302 itself, etc., can be suppressed more appropriately.Also, the length L2 of the elastic member 302 is, for example, not morethan 4 times the length L1 of the protrusion 24 p. Thereby, the largersize of the product can be suppressed appropriately.

In the optical receptacle 300, the average tilt angle θ2 between theouter surface of the elastic member 302 and the first rear end surfaceBS1 of the holder 20 is not less than the average tilt angle θ1 betweenthe outer surface of the protrusion 24 p and the first rear end surfaceBS1 of the holder 20. Thereby, the wall thickness of the elastic member302 can be ensured appropriately regardless of the final quality of thewidth of the elastic member 24 at the first rear end surface BS1 of theholder 20; and the damage of the elastic member 302 itself, etc., can besuppressed even when the optical fiber 14 is bent by stress from theoutside, etc.

FIG. 13A to FIG. 13C are partial cross-sectional views illustratingmodifications of the pigtail-type optical receptacle according to thefourth embodiment.

As illustrated in FIG. 13A, the average tilt angle θ2 between the outersurface of the elastic member 302 and the first rear end surface BS1 maybe smaller than the average tilt angle θ1 between the outer surface ofthe protrusion 24 p and the first rear end surface BS1.

However, in such a case, the wall thickness of the elastic member 302undesirably becomes thin partially. For example, the wall thickness ofthe elastic member 302 undesirably becomes thin at the portion on therear end side covering the boundary portion between the elastic member24 and the protective member 16. Therefore, the risk of the damage ofthe elastic member 302 itself undesirably increases when the opticalfiber 14 is bent by stress from the outside, etc. Accordingly, it isfavorable for the tilt angle θ2 to be the tilt angle θ1 or more.Thereby, as described above, the wall thickness of the elastic member302 can be ensured appropriately; and the damage of the elastic member302 itself, etc., can be suppressed.

As illustrated in FIG. 13B, the width W1 of the elastic member 24 may bewider than the width of the chamfer portion 20 c of the holder 20 in thedirection orthogonal to the axial direction. The elastic member 24 mayspread outward from the chamfer portion 20 c.

However, in such a case, for example, the difference between the widthW1 of the elastic member 24 and the width W2 of the elastic member 302becomes small; and it is undesirably difficult to form the elasticmember 302. Also, the wall thickness of the elastic member 302 at thevicinity of the first rear end surface BS1 becomes thin; and the risk ofthe damage of the elastic member 302 itself undesirably increases.Accordingly, it is favorable for the width W1 of the elastic member 24to be not more than the width of the chamfer portion 20 c of the holder20 in the direction orthogonal to the axial direction. Thereby, forexample, the elastic member 302 can be formed easily. The wall thicknessof the elastic member 302 can be ensured appropriately; and the damageof the elastic member 302 itself, etc., also can be suppressed.

As illustrated in FIG. 13C, the elastic member 24 may not include theprotrusion 24 p. Even in such a case, by providing the elastic member302, the damage of the protective member 16 at the boundary vicinitywith the elastic member 24 and/or the elastic member 302, etc., can besuppressed while suppressing the larger size of the product; and therisk of breakage of the optical fiber 14 can be reduced further.

This embodiment includes the following aspects.

Aspect 1

A pigtail-type optical receptacle, comprising:

a ferrule having a tubular configuration and having a through-holeextending in an axial direction;

an optical fiber held by the ferrule in a state of being inserted intothe through-hole, the optical fiber extending outside the ferrule from arear end side of the ferrule;

a protective member covering a portion of the optical fiber extendingoutside the ferrule;

a sleeve having a tubular configuration, engaging an outer surface ofthe ferrule, and being mounted on a front end side of the ferrule;

a holder having a tubular configuration, engaging the outer surface ofthe ferrule, and holding the rear end side of the ferrule; and

a housing having a tubular configuration, engaging an outer surface ofthe holder, and covering the ferrule and at least a portion of thesleeve,

the through-hole of the ferrule including a first region and a secondregion, a width in an orthogonal direction of the through-hole in thefirst region corresponding to a width in the orthogonal direction of theoptical fiber, the orthogonal direction being orthogonal to the axialdirection, the second region being disposed rearward of the firstregion, the width in the orthogonal direction of the through-hole in thesecond region widening toward the rear end side of the ferrule,

the holder holding a portion of the outer surface of the ferrulerearward of the first region.

Aspect 2

The receptacle according to aspect 1, wherein a change of the width inthe orthogonal direction of the through-hole in the second region has acurved configuration, the curved configuration being convex toward acentral axis side of the through-hole.

Aspect 3

The receptacle according to aspect 2, wherein

the through-hole of the ferrule further includes a third region disposedrearward of the second region, and

a change of the width in the orthogonal direction of the through-hole inthe third region has a linear configuration.

Aspect 4

The receptacle according to aspect 1, wherein a front end of theprotective member is positioned inside the second region of thethrough-hole.

Aspect 5

The receptacle according to aspect 3, wherein a front end of theprotective member is positioned inside the third region of thethrough-hole.

Aspect 6

The receptacle according to aspect 1, wherein the holder holds the rearend side of the ferrule by press-fitting.

Aspect 7

The receptacle according to aspect 1, wherein

a rear end of the holder is positioned rearward of the rear end of theferrule,

the holder surrounds a portion of the optical fiber and a portion of theprotective member, and the optical fiber and the protective memberfurther extend outside the holder and are fixedly bonded to the holderby an elastic member filled into the through-hole and into the holder.

Aspect 8

The receptacle according to aspect 7, wherein

an inner perimeter surface of the holder includes:

-   -   a first inner perimeter portion engaging the outer surface of        the ferrule; and    -   a second inner perimeter portion positioned rearward of the        first inner perimeter portion, the second inner perimeter        portion protruding inward from the first inner perimeter portion        and surrounding a portion of the optical fiber and a portion of        the protective member,

a gap is provided in the axial direction between the second innerperimeter portion and the rear end of the ferrule, and

the elastic member is filled also into the gap.

Aspect 9

The receptacle according to aspect 1, wherein the holder has a firstrear end surface and a second rear end surface, and

the second rear end surface is recessed frontward of the first rear endsurface on an outer perimeter side of the first rear end surface.

Aspect 10

The receptacle according to aspect 1, wherein

the outer surface of the holder includes:

-   -   a first outer perimeter portion held by the housing; and    -   a second outer perimeter portion provided at a front end portion        of the holder, the second outer perimeter portion being recessed        inward from the first outer perimeter portion.

Aspect 11

The receptacle according to aspect 1, wherein the holder includes achamfer portion between a rear end surface and an inner perimetersurface.

Aspect 12

The receptacle according to aspect 7, wherein the elastic memberincludes a protrusion protruding outside the holder on the rear end sideof the holder and covering a corner portion between the rear end of theholder and an outer surface of the protective member.

Aspect 13

The receptacle according to aspect 1, wherein the housing holds theholder by press-fitting.

Aspect 14

The receptacle according to aspect 1, wherein

the outer surface of the ferrule includes a first contact portioncontacting an inner perimeter surface of the holder,

the outer surface of the holder includes a second contact portioncontacting an inner perimeter surface of the housing, and

an intermediate point in the axial direction of the second contactportion is positioned rearward of an intermediate point in the axialdirection of the first contact portion.

Aspect 15

A pigtail-type optical receptacle, comprising:

a ferrule having a tubular configuration and having a through-holeextending in an axial direction;

an optical fiber held by the ferrule in a state of being inserted intothe through-hole, the optical fiber extending outside the ferrule from arear end side of the ferrule;

a protective member covering a portion of the optical fiber extendingoutside the ferrule;

a sleeve having a tubular configuration, engaging an outer surface ofthe ferrule, and being mounted on a front end side of the ferrule;

a holder having a tubular configuration, engaging the outer surface ofthe ferrule, and holding the rear end side of the ferrule; and

a housing having a tubular configuration, engaging an outer surface ofthe holder, and covering the ferrule and at least a portion of thesleeve,

the through-hole of the ferrule including a first region and a secondregion, a width in an orthogonal direction of the through-hole in thefirst region corresponding to a width in the orthogonal direction of theoptical fiber, the orthogonal direction being orthogonal to the axialdirection, the second region being disposed rearward of the firstregion, the width in the orthogonal direction of the through-hole in thesecond region widening toward the rear end side of the ferrule,

the width in the orthogonal direction of the through-hole in the secondregion changing in a curved configuration having a proportion of thechange increasing toward the rear end side.

Aspect 16

A pigtail-type optical receptacle, comprising:

a ferrule having a tubular configuration and having a through-holeextending in an axial direction;

an optical fiber held by the ferrule in a state of being inserted intothe through-hole, the optical fiber extending outside the ferrule from arear end side of the ferrule;

a protective member covering a portion of the optical fiber extendingoutside the ferrule;

a sleeve having a tubular configuration, engaging an outer surface ofthe ferrule, and being mounted on a front end side of the ferrule;

a holder having a tubular configuration, engaging the outer surface ofthe ferrule, and holding the rear end side of the ferrule; and

a housing having a tubular configuration, engaging an outer surface ofthe holder, and covering the ferrule and at least a portion of thesleeve,

the through-hole of the ferrule including a first region and a secondregion, a width in an orthogonal direction of the through-hole in thefirst region corresponding to a width in the orthogonal direction of theoptical fiber, the orthogonal direction being orthogonal to the axialdirection, the second region being disposed rearward of the firstregion, the width in the orthogonal direction of the through-hole in thesecond region widening toward the rear end side of the ferrule,

the housing engaging the outer surface of the holder rearward of thefirst region.

Aspect 17

The receptacle according to aspect 16, wherein

the outer surface of the holder includes:

-   -   a first outer perimeter portion held by the housing; and    -   a second outer perimeter portion provided at a front end portion        of the holder, the second outer perimeter portion being recessed        inward from the first outer perimeter portion, and

the first outer perimeter portion is positioned rearward of the firstregion.

Aspect 18

The receptacle according to aspect 16, wherein

an inner surface of the housing includes:

-   -   a first inner perimeter portion engaging the outer surface of        the holder; and    -   a second inner perimeter portion provided frontward of the first        inner perimeter portion, the second inner perimeter portion        widening outward from the first inner perimeter portion, and

the first inner perimeter portion is positioned rearward of the firstregion.

Aspect 19

The receptacle according to aspect 18, wherein the second innerperimeter portion is connected to the first inner perimeter portion viaa tilted surface or a curved surface.

Aspect 20

A pigtail-type optical receptacle, comprising:

a ferrule having a tubular configuration and having a through-holeextending in an axial direction;

an optical fiber held by the ferrule in a state of being inserted intothe through-hole, the optical fiber extending outside the ferrule from arear end side of the ferrule;

a protective member covering a portion of the optical fiber extendingoutside the ferrule;

a sleeve having a tubular configuration, engaging an outer surface ofthe ferrule, and being mounted on a front end side of the ferrule;

a holder having a tubular configuration, engaging the outer surface ofthe ferrule, and holding the rear end side of the ferrule; and

a housing having a tubular configuration, being mounted to the holder,and covering the ferrule and at least a portion of the sleeve,

the through-hole of the ferrule including a first region and a secondregion, a width in an orthogonal direction of the through-hole in thefirst region corresponding to a width in the orthogonal direction of theoptical fiber, the orthogonal direction being orthogonal to the axialdirection, the second region being disposed rearward of the firstregion, the width in the orthogonal direction of the through-hole in thesecond region widening toward the rear end side of the ferrule,

the holder including a flange protruding outward from the housing, theflange being provided frontward of the second region,

the housing being mounted to the holder frontward of the flange.

Aspect 21

A pigtail-type optical receptacle, comprising:

a ferrule having a tubular configuration and having a through-holeextending in an axial direction;

an optical fiber held by the ferrule in a state of being inserted intothe through-hole, the optical fiber extending outside the ferrule from arear end side of the ferrule;

a protective member covering a portion of the optical fiber extendingoutside the ferrule;

a sleeve having a tubular configuration, engaging an outer surface ofthe ferrule, and being mounted on a front end side of the ferrule;

a holder having a tubular configuration, engaging the outer surface ofthe ferrule, and holding the rear end side of the ferrule;

a housing having a tubular configuration, engaging an outer surface ofthe holder, and covering the ferrule and at least a portion of thesleeve;

a first elastic member filled into the through-hole and into the holder;and

a second elastic member covering a corner portion between a rear end ofthe holder and the outer surface of the protective member,

the through-hole of the ferrule including a first region and a secondregion, a width in an orthogonal direction of the through-hole in thefirst region corresponding to a width in the orthogonal direction of theoptical fiber, the orthogonal direction being orthogonal to the axialdirection, the second region being disposed rearward of the firstregion, the width in the orthogonal direction of the through-hole in thesecond region widening toward the rear end side of the ferrule,

the holder holding a portion of the outer surface of the ferrulerearward of the first region,

the rear end of the holder being positioned rearward of the rear end ofthe ferrule,

the holder surrounding a portion of the optical fiber and a portion ofthe protective member,

the optical fiber and the protective member further extending outsidethe holder and being fixedly bonded to the holder by the first elasticmember,

a hardness of the second elastic member being lower than a hardness ofthe first elastic member.

Aspect 22

A pigtail-type optical receptacle, comprising:

a ferrule having a tubular configuration and having a through-holeextending in an axial direction;

an optical fiber held by the ferrule in a state of being inserted intothe through-hole, the optical fiber extending outside the ferrule from arear end side of the ferrule;

a protective member covering a portion of the optical fiber extendingoutside the ferrule;

a sleeve having a tubular configuration, engaging an outer surface ofthe ferrule, and being mounted on a front end side of the ferrule;

a holder having a tubular configuration, engaging the outer surface ofthe ferrule, and holding the rear end side of the ferrule;

a housing having a tubular configuration, engaging an outer surface ofthe holder, and covering the ferrule and at least a portion of thesleeve;

a first elastic member filled into the through-hole and into the holder;and

a second elastic member covering a corner portion between a rear end ofthe holder and the outer surface of the protective member,

the through-hole of the ferrule including a first region and a secondregion, a width in an orthogonal direction of the through-hole in thefirst region corresponding to a width in the orthogonal direction of theoptical fiber, the orthogonal direction being orthogonal to the axialdirection, the second region being disposed rearward of the firstregion, the width in the orthogonal direction of the through-hole in thesecond region widening toward the rear end side of the ferrule,

the width in the orthogonal direction of the through-hole in the secondregion changing in a curved configuration having a proportion of thechange increasing toward the rear end side,

the rear end of the holder being positioned rearward of the rear end ofthe ferrule,

the holder surrounding a portion of the optical fiber and a portion ofthe protective member,

the optical fiber and the protective member further extending outsidethe holder and being fixedly bonded to the holder by the first elasticmember,

a hardness of the second elastic member being lower than a hardness ofthe first elastic member.

Aspect 23

A pigtail-type optical receptacle, comprising:

a ferrule having a tubular configuration and having a through-holeextending in an axial direction;

an optical fiber held by the ferrule in a state of being inserted intothe through-hole, the optical fiber extending outside the ferrule from arear end side of the ferrule;

a protective member covering a portion of the optical fiber extendingoutside the ferrule;

a sleeve having a tubular configuration, engaging an outer surface ofthe ferrule, and being mounted on a front end side of the ferrule;

a holder having a tubular configuration, engaging the outer surface ofthe ferrule, and holding the rear end side of the ferrule;

a housing having a tubular configuration, engaging an outer surface ofthe holder, and covering the ferrule and at least a portion of thesleeve;

a first elastic member filled into the through-hole and into the holder;and

a second elastic member covering a corner portion between a rear end ofthe holder and an outer surface of the protective member,

the through-hole of the ferrule including a first region and a secondregion, a width in an orthogonal direction of the through-hole in thefirst region corresponding to a width in the orthogonal direction of theoptical fiber, the orthogonal direction being orthogonal to the axialdirection, the second region being disposed rearward of the firstregion, the width in the orthogonal direction of the through-hole in thesecond region widening toward the rear end side of the ferrule;

the housing engaging the outer surface of the holder rearward of thefirst region,

the rear end of the holder being positioned rearward of the rear end ofthe ferrule,

the holder surrounding a portion of the optical fiber and a portion ofthe protective member,

the optical fiber and the protective member further extending outsidethe holder and being fixedly bonded to the holder by the first elasticmember,

a hardness of the second elastic member being lower than a hardness ofthe first elastic member.

Aspect 24

A pigtail-type optical receptacle, comprising:

a ferrule having a tubular configuration and having a through-holeextending in an axial direction;

an optical fiber held by the ferrule in a state of being inserted intothe through-hole, the optical fiber extending outside the ferrule from arear end side of the ferrule;

a protective member covering a portion of the optical fiber extendingoutside the ferrule;

a sleeve having a tubular configuration, engaging an outer surface ofthe ferrule, and being mounted on a front end side of the ferrule;

a holder having a tubular configuration, engaging the outer surface ofthe ferrule, and holding the rear end side of the ferrule;

a housing having a tubular configuration, being mounted to the holder,and covering the ferrule and at least a portion of the sleeve;

a first elastic member filled into the through-hole and into the holder;and

a second elastic member covering a corner portion between a rear end ofthe holder and an outer surface of the protective member,

the through-hole of the ferrule including a first region and a secondregion, a width in an orthogonal direction of the through-hole in thefirst region corresponding to a width in the orthogonal direction of theoptical fiber, the orthogonal direction being orthogonal to the axialdirection, the second region being disposed rearward of the firstregion, the width in the orthogonal direction of the through-hole in thesecond region widening toward the rear end side of the ferrule,

the holder including a flange protruding outward from the housing, theflange being provided frontward of the second region,

the housing being mounted to the holder frontward of the flange,

the rear end of the holder being positioned rearward of the rear end ofthe ferrule,

the holder surrounding a portion of the optical fiber and a portion ofthe protective member,

the optical fiber and the protective member further extending outsidethe holder and being fixedly bonded to the holder by the first elasticmember,

a hardness of the second elastic member being lower than a hardness ofthe first elastic member.

Aspect 25

The receptacle according to aspect 21, wherein a width of the secondelastic member at a rear end surface of the holder is wider than a widthof the first elastic member at the rear end surface of the holder.

Aspect 26

26. The receptacle according to aspect 21, wherein

the holder has a first rear end surface and a second rear end surface,

the second rear end surface is recessed frontward of the first rear endsurface on an outer perimeter side of the first rear end surface, and

a width in a direction orthogonal to the axial direction of the secondelastic member is narrower than a width in the direction orthogonal tothe axial direction of the first rear end surface.

Aspect 27

The receptacle according to aspect 21, wherein

the first elastic member includes a protrusion protruding outside theholder on the rear end side of the holder,

the protrusion covers a corner portion between the rear end of theholder and the outer surface of the protective member, and

the second elastic member covers the protrusion.

Aspect 28

The receptacle according to aspect 27, wherein a length in the axialdirection of the second elastic member is longer than a length in theaxial direction of the protrusion.

Aspect 29

The receptacle according to aspect 27, wherein an average tilt anglebetween an outer surface of the second elastic member and a rear endsurface of the holder is not less than an average tilt angle between anouter surface of the protrusion and the rear end surface of the holder.

Embodiments of the invention are described hereinabove. However, theinvention is not limited to these descriptions. Appropriate designmodifications performed by one skilled in the art based on theembodiments described above also are within the scope of the inventionto the extent that the features of the invention are included. Forexample, the configuration, the dimensions, the material properties, thearrangement, etc., of each component included in the optical receptacles10, 10 a, 10 b, 100, 100 a, 200, 200 a, 200 b, 300, etc., are notlimited to those illustrated and can be modified appropriately.

Also, the components included in the embodiments described above can becombined within the limits of technical feasibility; and suchcombinations are within the scope of the invention to the extent thatthe features of the invention are included.

What is claimed is:
 1. A pigtail-type optical receptacle, comprising: aferrule having a tubular configuration and having a through-holeextending in an axial direction; an optical fiber held by the ferrule ina state of being inserted into the through-hole, the optical fiberextending outside the ferrule from a rear end side of the ferrule; aprotective member covering a portion of the optical fiber extendingoutside the ferrule; a sleeve having a tubular configuration, engagingan outer surface of the ferrule, and being mounted on a front end sideof the ferrule; a holder having a tubular configuration, engaging theouter surface of the ferrule, and holding the rear end side of theferrule; and a housing having a tubular configuration, engaging an outersurface of the holder, and covering the ferrule and at least a portionof the sleeve, the through-hole of the ferrule including a first regionand a second region, a width in an orthogonal direction of thethrough-hole in the first region corresponding to a width in theorthogonal direction of the optical fiber, the orthogonal directionbeing orthogonal to the axial direction, the second region beingdisposed rearward of the first region, the width in the orthogonaldirection of the through-hole in the second region widening toward therear end side of the ferrule, the housing engaging the outer surface ofthe holder rearward of the first region.
 2. The receptacle according toclaim 1, wherein the outer surface of the holder includes: a first outerperimeter portion held by the housing; and a second outer perimeterportion provided at a front end portion of the holder, the second outerperimeter portion being recessed inward from the first outer perimeterportion, and the first outer perimeter portion is positioned rearward ofthe first region.
 3. The receptacle according to claim 1, wherein aninner surface of the housing includes: a first inner perimeter portionengaging the outer surface of the holder; and a second inner perimeterportion provided frontward of the first inner perimeter portion, thesecond inner perimeter portion widening outward from the first innerperimeter portion, and the first inner perimeter portion is positionedrearward of the first region.
 4. The receptacle according to claim 3,wherein the second inner perimeter portion is connected to the firstinner perimeter portion via a tilted surface or a curved surface.